NOTE: below is ESPP’s understanding to date and may not be fully accurate. Please verify with cited source documents.
European Commission proposes regulatory package to reduce greenhouse gas emissions by -55% to 2030, including actions on agriculture and land use, and a Carbon Border Adjustment Mechanism (CBAM) for nitrogen fertilisers. The Green Deal “Fit for 55” published (14th July 2021) is a detailed regulatory package, intending to “transform the economy”” to reduce greenhouse gas emissions, including proposals on transports, including road and aviation fuel taxes and banning sales of greenhouse gas (GHG) emitting cars by 2035, energy efficiency and changes to the EU Emissions Trading System (ETS). The package includes a proposal to avoid ‘carbon leakage’ by putting a carbon price on imports of certain goods (Cross Border Adjustment Mechanism CBAM), starting with cement, iron and steel, aluminium, electricity and (nitrogen) fertilisers. The proposed CBAM Regulation (Com(2021)564) proposes the border carbon tax on N, N+P, N+K and NPK mineral/chemical fertilisers, noting that the “difference in emission intensities of EU and non-EU producers is particularly high for fertilisers”. Mineral phosphorus fertilisers are not concerned if not containing nitrogen. Fertilizers Europe has expressed support in principle for the CBAM on fertilisers: Jacob Hansen, Director General, 11th March 2021 “Fertilizers Europe … recognises that to raise EU’s ambition on climate while avoiding carbon leakage, the EU must put a carbon border measure in place to ensure an international level playing field”.
The proposed Regulation on Climate-Neutral Land Use, Forestry and Agriculture (COM(2021)504) proposes to implement binding targets for Member States for net carbon removal in land use and aims to make food and biomass production climate neutral by 2035, in particular citing livestock and fertiliser use. The proposal indicates inclusion of greenhouse emissions related to “nitrogen leaching and run-off” but does not specify how such nitrogen losses are calculated to relate to greenhouse emissions.
Raw materials and nutrients are otherwise absent from the “Fit for 55” package, which addresses principally energy. This is coherent in that nutrients are strongly addressed elsewhere under the Green Deal Farm-to-Fork and Biodiversity packages, see SCOPE Newsletter n°139.
NGOs are critical of the “Fit for 55” package, suggesting that it is insufficiently ambitious, criticising the absence of sector-specific emissions reduction targets, exclusion of heavy industry and agriculture from ETS and continuing subsidies to fossil fuels.
European Commission press release, 14th July 2021 IP_21_3541) “European Green Deal: Commission proposes transformation of EU economy and society to meet climate ambitions” https://ec.europa.eu/commission/presscorner/detail/en/ip_21_3541
Fertilizers Europe press release 11th March 2021
European Environment Bureau “EU’s ‘Fit for 55’ is unfit and unfair”, 14th July 2021.
Wide media coverage points to “contamination of nearly the whole French population, including children, by heavy metals”, and says breakfast cereals are the main source of cadmium, because of phosphate fertilisers. The documents published by Public Health France are less directly accusatory, but do state that cadmium levels in the French population increased from 2006-2007 to 2014-2016 and are higher than in other European countries or North America. The official website states that breakfast cereals increase cadmium levels in children, with fish, shellfish and smoking being important other sources for adults. Nearly half the French population show cadmium levels higher than that recommended by the French national health and environment agency ANSES. The official study report (ESTEBAN) indicates that in 2019 this agency (ANSES) recommended to reduce population exposure to cadmium, in particular in mineral phosphate fertiliser and organic soil amendments such as sewage biosolids. The ESTEBAN report quotes INERIS 2017 “reduction of cadmium in fertilisers seems to meet economic rather than technical obstacles”.
Nouvelle République 5/7/21 (article published widely across France) here and Le Monde here.
SantéPubliqueFrance press release 1/7/2021 here.
ESTEBAN (French national biosurveillance) report “Impregnation of the French population by cadmium”, July 2021 here and press release 1/7/2021 here.
Proposed new EU (CEN) standards are published and open to comment, for wastewater treatment plants: chemical phosphorus precipitation and general data requirements. prEN 12255-13 covers “chemical treatment of wastewater by precipitation/flocculation for removal of phosphorus and suspended solids”. It defines terms such as “coagulant”, “tertiary treatment”, “precipitant”. The standard indicates that P-total discharge limits “typically range from 2 mg/l down to 0.25 mg/”. The standard provides guidance for design, chemical process options, selection of precipitation chemicals, storage – preparation and dosing of chemicals, mixing, control systems, reactor - sedimentation and filtration systems, and sludge production. prEN 12255-11 covers data necessary for planning, design, construction, compliance testing, etc. of wastewater treatment plants.
Both standards are now published as drafts, and comments can be input via national standards organisations.
As usual for CEN standards, the draft texts are not freely available, and prices vary depending on different national standards body website. Texts of both standards can be purchased for a total of 9.75€ from the Estonia standards organisation www.evs.ee
The European Commission (JRC) has announced a stakeholder workshop to discuss which materials streams should be on a priority list for definition of European End-of-Waste Criteria. ESPP submitted at the start of May 2021 a joint letter, signed by over 120 companies and organisations, requesting that certain material streams recovered from waste water be considered for this priority list. (This does not concern recovered materials used in fertilising products, for which the EU Fertilising Products Regulation 2019/1009 provides a process for defining End-of-Waste status). Eureau, AquaPublica, ESPP and other organisations are now mandating an expert to provide further information on these material streams to support this request. The material streams suggested by JRC for discussion at this workshop include “biological materials” and it is not today clear whether materials from wastewater may be considered under this title.
European Commission JRC stakeholder workshop “Scoping and developing further End-of-Waste (EoW) and By-Product (BP) criteria”, online, 14-15 September 2021. Participation of organisations selected by the European Commission only. To candidate to participate: contact before 30th July 2021.
Twitter: #EoW4WWStreams
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Link to www.phosphorusplatform.eu/eNews056
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7th July 2021, 10h30 - 16h30 CEST. Online conference will look at current status and future developments in phosphorus removal from wastewater, P-stewardship and P-recovery. Speakers include the UK Environment Agency, Isle Utilities, I-PHYC, The Rivers Trust, several UK water companies, ESPP.
https://event.wwtonline.co.uk/phosphorus/
29th June 2021 13h-15h CEST – free webinar organised by Fertiliser Consultants Network (FCN). Key points of the new EU Fertilising Products Regulation. How to manage fertiliser registration in the transitional period 2021-2024. Specific country/regional registration: France, Greece, Romania, North Africa, India,
Programme and registration https://www.legera.eu
Speaker slides and the ‘Chat’ from the 4th Phosphorus in Europe Research Meeting (PERM) are now online here and the video recordings of the event are available on YouTube here.
Over 370 participants took part in the 4th Phosphorus in Europe Research Meeting (PERM) 2nd June 2021 online, organised by ESPP, Biorefine and ETA. The meeting provided a showcase to policy makers and companies of R&D underway into nutrients in Europe, enabled exchange of experience between R&D projects.
PERM4 is accompanied by a full update of ESPP’s inventory of nutrient-related R&D projects now online here www.phosphorusplatform.eu/R&D
PERM4 web page: www.phosphorusplatform.eu/PERM4
OCP Group, a leading, global producer of phosphate and fertiliser, was founded in 1920 to manage Morocco’s phosphate reserves, and is today focussed on sustainable agriculture. OCP’s purpose and mission is to “maximize the positive impact of phosphorus”. The company’s Phosphate Stewardship Policy underlines its strong commitment to sustainably managing Morocco’s phosphate resource and is aligned with the UN’s 2030 Agenda and the Sustainable Development Goals, specifically SDG 12: “Ensure sustainable consumption and production patterns”. Sustainable phosphate management is applied across OCP’s operations and sites; through product innovation and in R&D on re-working and recycling of phosphate resources; through its work with farmers around the world and the application of customised fertilisers; and in the development of technologies at its Mohammed VI Polytechnic University. OCP is engaged in efforts to study and develop means to effectively recycle phosphorus after its initial use to reduce the amount of mined phosphate required to produce the same quantity of food. In Africa, OCP has worked with more than one million farmers to educate on the importance of sustainable fertiliser application to maximise yields while preserving the integrity of the soil. OCP Group has developed more than forty customised fertiliser formulas for maximum efficiency and sustainable application, and to explore new technologies and products such as biostimulants and slow release fertilisers, among others, with the objective of an optimal consumption of the phosphate resource. OCP has been a founding member of the North America Sustainable Phosphorus Alliance and has now joined ESPP.
The European Commission has published its third report towards criteria for using “By-Products” as Component Materials for EU fertilising products (CMC11, additives and CMC-WW) for comment by 16th August 2021, under the new EU Fertilising Products Regulation 2019/1009). The 180-page document now proposes detailed criteria for which families of by-product would be eligible, with proposed quality/purity criteria, contaminant limits, process input material exclusions, etc. This was discussed at the EU Fertilisers Expert Group 24-25 June, at which ESPP was represented.
The following summarises ESPP’s understanding of the JRC proposal.
ESPP welcomes positively that phosphogypsum and other mineral processing by-products are included, and that a new route is opened to include nitrogen salts recovered from biogas or manure or animal housing gas treatment. However, this will probably only cover recovery from sanitised manure, unless data can be produced to show the safety (absence of pathogens) in such materials (see below).
The new proposal is significantly narrower than was suggested in March this year (CMC-WW initial proposal, see ESPP eNews n°53). ESPP’s request to widen to “derivates” (see ESPP eNews n°54) has not been taken up, that is the eligible by-products can only be included directly, as such, in an EU fertilising product, that is with no further chemical processing. They cannot be used as a precursor to produce other materials (note that by-products can be used as precursors in CMC1, but not if they have “waste” status).
The new JRC proposal is somewhat complex, with four different routes:
Routes (1) and (2) are subject to the requirements that (a) the material must be a “by-product” as defined under the Waste Framework Directive 2008/98/EC, (b) Animal By-Products, polymers, compost and digestate are excluded, and (c) the material must be REACH registered (with conditions). For routes (1) and (2) a specific list of contaminant limits is defined.
(1) By-products from seven specified industrial processes: methionine, mineral ore processing (this category includes by-product gypsums and phosphogypsums), Solvay process, acetylene production, ferrous slags, specific metal treatments, humic/fulvic acids from drinking water treatment;
(2) (any) by-product used as a “technical additive” at <5% total in the final EU fertilising product.
Routes (3) and (4) are “CMC-WW High Purity Materials”, which was originally proposed in March this year (see ESPP eNews n°54). This proposal has been significantly narrowed and now covers ONLY mineral salts of ammonia, sulphur (inc. elemental sulphur), calcium carbonate or calcium oxide, subject to 95% purity and organic carbon < 0.5%. These mineral salts must also respect a detailed and extensive limits of contaminant limits, and must be REACH registered (with conditions). They can result from:
(3) any “production” process, to which inputs can be any material (chemicals, biomass …), but NOT waste and NOT Animal By-Products
(4) gas purification from (to simplify): hygienised manure, non-hazardous wastes or any other material except Animal By-Products. The list currently includes livestock housing offgas and gas from on-farm, storage of non-hygienised manure, but these are liable to be deleted]
European Commission JRC “Technical proposals for by-products and high purity materials as component materials for EU Fertilising Products. Interim report”, 14 June 2021 https://circabc.europa.eu/ui/group/36ec94c7-575b-44dc-a6e9-4ace02907f2f/library/785d1835-07b3-4b3c-a46a-e269a33c74c7/details
Comments are open to 16th August but can only be submitted via members of the EU Fertilisers Expert Group. Please therefore send all comments to ESPP before 16th July, in order to enable them to be taken into account.
At the EU Fertilisers Expert Group, 24-25 June, of which ESPP is a member:
The European Commission DG SANTE summarised slow progress on criteria for using Animal By-Products (ABPs) in EU fertilising products (currently an ‘empty box’ in CMC10 in the Fertilising Products Regulation 2019/1009 = FPR). Work has not yet started on End-Points for ABPs under the FPR, but that the EFSA opinion is expected on some materials in September 2021 (EFSA mandate 2020-0088, see ESPP eNews n°50). It thus seems inevitable that the End-Point criteria will not be adopted by the date of entry into application of the FPR in July 2022. This is the regrettable consequence of the fact that the mandate to EFSA was only transmitted by DG SANTE to EFSA in May 2020, nearly a year after publication of the FPR and more than four years after publication of the proposed regulation which already included the CMC10 ‘empty box’.
The Commission presented development of the ‘FAQ’ which provides guidance on the FPR. New adjustments clarify on additives, contaminants in CMC materials, waste plant materials (CMC2), definitions of ‘sludge’, blue green algae.
It is confirmed that plant materials with waste status (e.g. garden waste) can be used as input to CMC2 (subject to the processing limits specified) and so achieve End-of-Waste status when integrated into an EU-label fertilising product.
Pyrolysis products and biochars from manure and Animal By-Products: DG SANTE indicated that if companies wish these to be included in the FPR, then they should submit a dossier to EFSA requesting an ABP End-Point. At present, there is no Commission mandate to EFSA to develop an ABP End-Point for pyrolysis, gasification and biochar materials. Until such an ABP End-Point is defined and adopted, biochars from manure or animal by-products will be excluded from EU fertilisers. Companies with data showing pathogen safety of biochars from manure or animal by-products are invited to contact ESPP to develop together a dossier for EFSA.
STRUBIAS criteria moving towards adoption. The European Commission confirmed that the EU Fertilising Products Regulation criteria for precipitated phosphate salts, ash-derived products and biochars/pyrolysis materials (STRUBIAS) are progressing towards Commission adoption, which will be followed by the standard three month ‘objection’ period, before publication, so should be published significantly before entre into application of the Regulation in July 2022.
ESPP letter to the European Commission on “Animal By Product End Points for EU Fertilising Products Regulation STRUBIAS materials”, 16th April 2021 www.phosphorusplatform.eu/regulatory
STRUBIAS criteria, as published for the public consultation February 2021
The principle of inclusion of ammonia or sulphur materials recovered from gas stripping in EU-fertilisers seems now accepted (CMC-WW) but those from manure may be excluded, unless data is available on pathogen levels and safety. Nitrogen and sulphur materials recovered from gas cleaning in anaerobic digesters, sewage works, waste incinerators or other installations look likely to be included in the new CMC-WW of the EU Fertilising Product Regulation (see above). However, recovery from (non-sanitised) manure, manure digestion, livestock stables or other animal by-products will likely be excluded unless data is provided to show absence of pathogens and hygiene safety. It seems probable that the transfer via the gas phase, then acid stripping and concentration in mineral solutions, prevents or eliminates pathogens, but to date very little data has been provided to the Commission. Data will also support an ongoing ESPP request to exonerate such recovered materials from the Animal Feed regulation clause which currently prevents placing them on the market as commodity chemicals. Possibly also, a request to EFSA should be prepared to develop and Animal By-Product End-Point for such recovery processes.
If you have such data, or are willing to cooperate in developing such data (analysis of recovered nitrogen or sulphur materials), please contact ESPP.
The European Commission has opened to 31st August a tender to assess biodegradability criteria for polymers used in fertilisers (coating agents, water retention, wettability) or in mulch films. Value: up to 300 000 €.
Submission deadline 31st August 2021. TED (EU tender website) Services 311603-2021 link.
Belgium, France, Greece, Hungary and Spain face European Court of Justice action over inadequate collection and treatment of municipal wastewater.
The European Commission has referred France to the European Court of Justice (ECJ) for failure to adequately treat sewage of more than 100 agglomerations (non-compliance with the 1991 Urban Waste Water Treatment Directive 91/271/EEC, which should have been fully implemented by 2005). Fifteen of these French agglomerations also fail to meet additional treatment requirements in eutrophication Sensitive Areas (phosphorus removal).
The Commission is also referring Hungary to the ECJ because 22 agglomerations are not collecting all residents’ sewage, relying instead partly on individual treatment systems (septic tanks), which are considered to not provide adequate treatment.
The Commission has issued a Reasoned Opinion to Belgium for non-compliance of 11 agglomerations: this gives the Member State two months to reply and take necessary measures, or face referral to the (ECJ).
The Commission has issued a Reasoned Opinion to Spain concerning over 300 agglomerations which do not treat sewage adequately, and a further 30 agglomerations where sewage is not collected and treated centrally, instead relying on individual treatment systems.
European Commission “June infringements package: key decisions”, Brussels, 9 June 2021 https://ec.europa.eu/commission/presscorner/detail/en/inf_21_2743
“Urban Waste Water: Commission decides to refer FRANCE to the Court of Justice over waste water treatment”, 9 June 2021 https://ec.europa.eu/commission/presscorner/detail/en/ip_21_1546
The EU-funded project SYSTEMIC has presented for discussion proposals for EU policies to enable nutrient recovery to economic, in particular by bringing recycled nitrogen fertilisers into the EU Emissions Trading System. SYSTEMIC proposes to open carbon credits for biogas plant operators not only for bio-methane but also, if nitrogen is recovered and recycled, for avoided carbon emissions for production of equivalent mineral nitrogen fertilisers. It is proposed also to open carbon credits for farmers using recycled N fertilisers and for fertiliser companies who include recycled N into their products. These proposals are based on LCA data which suggests a benefit of 3 tCO2-eq per tonne N comparing recycled N fertilisers1 (assumed zero CO2 emissions, as using energy from waste biogas) to mineral fertilisers1. As proposed by SYSTEMIC, however, such carbon credits could penalise farmers who use manure on-farm and benefit large-scale livestock production, in that SYSTEMIC combines the carbon credit proposal with support for the JRC ‘RENURE’ concept which is considered by some as an attempt to facilitate intensive livestock production (see ESPP eNews n°47). It should be ensured that small and extensive farms can be equally rewarded for appropriate manure management. The carbon credit base is not applicable to recycled phosphorus, but could perhaps be transposed into a Nutrient Emissions Trading System with phosphorus credits.
1: EU average CO2-eq. per tonne N, from Hoxha & Christersen, IFS Proceedings 805, 2018
SYSTEMIC is an EU Horizon 2020 project and an ESPP member. SYSTEMIC webinar ““Enabling the Circular Economy: How to encourage a viable agricultural market for nutrients recovered from biowaste”, 13 June 2021. Watch here.
This journal issue includes 11 papers addressing phosphorus use in fertilisers and in soils. Six of these which include data relevant to discussions of ‘Legacy Phosphorus’ are summarised below. The other papers concern modelling, biostimulant bacteria, use of paper mill biosolids or sewage sludge. The editorial of this journal (Gatiboni et al.) suggests that the two Zhang et al. studies show that soil “Legacy Phosphorus” can be reduced without deteriorating crop productivity, whereas this is only demonstrated in a situation where initial soil P is higher than recommended, and that cropping with fertilisation can increase legacy P, whereas this is only shown in the scenario of P-fertilising grassland but not harvesting the grass (this could occur for example in grass buffer strips receiving P from runoff/erosion). The editorial also suggests that de Souza Nunes et al. shows that fertiliser application tends to accumulate legacy P: this is also misleading in that this study started with initially “very low” soil P where increasing the soil P was necessary for productive agriculture.
The editorial does not mention several conclusions which can be suggested from the six papers summarised above:
In correspondence with the editors, it was noted that this discussion contributes to debate, and underlines the conundrum of sustainable production: how to balance maximising yield against protecting the environment. Lower phosphate inputs and reduction of soil P levels, possibly below agronomic optimum levels, may be necessary to achieve environmental objectives, but will reduce productivity, maybe considerably (see eg. McDowell et al. below), with impacts for both food production and farmers’ incomes.
“Legacy Phosphorus in Agriculture: Role of Past Management and Perspectives for the Future”, 143 pagers in total, ed. L. Gatiboni et al., Frontiers in Environmental Science, January 2021, Legacy Phosphorus in Agriculture https://www.frontiersin.org/research-topics/10116/legacy-phosphorus-in-agriculture-role-of-past-management-and-perspectives-for-the-future#articles
Zhang et al. report data from 11 years’ field trials comparing P-fertiliser application to zero-P application in Ontario, Canada (Lake Erie catchment). Within the field, randomised plots of 0.1 ha each were given P fertiliser (50 kgP/ha once every two years), plus N+K, or only N+K, in soy /maize rotations, with fertilisers only in the maize years. Surprisingly given the random plot allocation, the soil Olsen P was initially considerably higher in the plots not receiving fertiliser (c. 60 mg/kg Olsen P in the top 15 cm of soil, versus c. 40 in the P-fertilised plots). 30 mg/kg is the agronomic recommended Olsen P level for maize and soybean. The soil Olsen P was nearly the same in the P-fertilised and unfertilised plots after 11 years, at the end of the trials, because it remained approximately constant in the P-fertilised plots but fell in the unfertilised plots. Crop productivity and crop P-offtake were similar in P-fertilised and unfertilised plots. The authors calculate that in the unfertilised plots net P-removal in crops was around 18 kgP/ha/year, so that in the P-fertilised net P-balance would be around +7 kgP/ha/y. Despite this, soil Olsen P did not measurably increase in these plots over the 11 years.
This study shows that soil Olsen P levels higher than agronomic recommendations do not lead to increased crop productivity. While the study is to continue, it is too early to inform as to whether or not crop productivity will be lost if soil P levels are “drawn down” below agronomic recommended levels.
“An 11-Year Agronomic, Economic, and Phosphorus Loss Potential Evaluation of Legacy Phosphorus Utilization in a Clay Loam Soil of the
Lake Erie Basin”, T. Zhang et al., Front. Earth Sci. 8:115 https://dx.doi.org/10.3389/feart.2020.00115
Zhang et al. assess data from long-term field trials, Ontario, Canada, comparing different soil P fractions after 45 years of NPK phosphorus fertilisation to no fertilisation (no P, no N, no K), under three different tile-drained cropping systems: harvested maize, harvested oats-alfalfa rotation or permanent (i.e. not annually ploughed), unharvested grass, comparing also to non-cropped, non drained woodland. The fertilised fields received NPK fertiliser with 29 kgP/ha/year. A previous study suggested that c. 1.5 kgP/ha/y is lost in tile drains. The fertiliser application, after 45 years, resulted in no significant increase in total soil P in the two harvested crops (compared to the woodland soil) but an increase in the fertilised, non-harvested grassland (this is not representative of real farm operation where fertilised grass is harvested and removed, resulting in P-offtake). All the cropped fields without fertilisation, including to a lesser extent the grassland, showed significantly lower total soil P after 45 years. Changes in the different solubility fractions of organic and inorganic fractions of P in the soils are assessed, showing that the rate of mineralisation of organic P is increased with cropping + drainage, with or without NPK fertilisation.
“Legacy Phosphorus After 45 Years With Consistent Cropping Systems and Fertilization Compared to Native Soils”, T. Zhang et al., Soils. Front. Earth Sci. 8:183 https://dx.doi.org/10.3389/feart.2020.00183
McDowell et al. analysed c. 4.5 million data points for Olsen P from two soil sample databases (Eurofins + Hills Labs, ARL) from commercial farms in New Zealand 2001-2015. Nearly half of these were for dairy, a further third for sheep and beef, <25% cropland and some horticulture. Nearly two thirds of samples showed Olsen P higher than agronomic recommendations. Modelling suggested that not applying P fertilisers would result in a fall in Olsen P to agronomic recommended levels in less than one year. This would not however correspond to environmental objectives, and reducing P-losses in drainage and runoff water to 0.02 mgP/l would require soil P levels significantly lower than agronomic recommendations. It would take 26-55 years for soils to reach environmental targets and the cessation of fertiliser inputs would likely result in large losses in agricultural productivity (these losses are not estimated).
“The Ability to Reduce Soil Legacy Phosphorus at a Country Scale”, R. McDowell et al., Front. Environ. Sci. 8:6 https://dx.doi.org/10.3389/fenvs.2020.00006
Messiga et al. report results of a total of eleven 1-year silage maize field trials at 3 sites in 2018 and 8 in 2019 in BC, Canada, each with six treatments x 4 replicates on 45 m2 plots: five treatments with a total of 35 kg available-P/ha (of which 0 – 20 from TSP [triple super phosphate] and the remainder from liquid dairy manure) and one control (zero P). 35% of manure P was estimated to be “available”. The TSP fertiliser was band applied immediately after seeding the maize whereas the manure was applied at the 6-leaf stage. Additional N was applied as ammonium nitrate at the 6-leaf stage to meet the local recommendation of 150 kg N/ha. Generally, dry matter yield (DMY) at harvest was not higher in the plots with added P (be it as starter fertiliser or as manure at the 6-leaf stage) compared to the zero-P plots (fig. 4). At four sites, DMY did increase with P, showing optimum with low starter fertiliser and most P input from manure. Maize initial growth was improved by the starter fertiliser application, but this did not carry through to harvest. DMY at harvest did however vary strongly with initial soil phosphorus index, from 15 t/ha DMY in sites with low initial soil P (Mehlich-3 60 mgP/kg) to nearly the double (27 t/ha DMY) at sites with high initial soil P (Mehlich-3 200 mgP/kg). The authors note that the soil PSI (Phosphorus Saturation Index, an agro-environmental indicator), a proxy for DPS (Degree of P Saturation), is correlated to DMY, so may be a good indicator for adjusting P application. Overall, the trial results seem to suggest that initial soil P (that is, legacy P) generally influences maize productivity much more than P application in the year.
“Combined Starter Phosphorus and Manure Applications on Silage Corn Yield and Phosphorus Uptake in Southern BC”, A. Messiga et al., Front. Earth Sci. 8:88, https://dx.doi.org/10.3389/feart.2020.00088
Soltangheisi et al. report results of nine years of field trials (25 m2 plots) in South Brazil, no-till cultivating each year maize and a winter cover crop. 3x6 treatments were trialled: no-P, single super phosphate mineral fertiliser (SSP, 46-59 kgP/ha) or Algerian rock phosphate (148-190 kgP/ha), but in all cases with no-P for the last two years x 5 different winter cover crops or no cover crop (fallow). The soil at the start of the nine years was considered to have low P in the top 0 – 10 cm and very low P at 10 – 20 cm depth, despite commercial no-till cultivation for the years prior to the trials. P-fractions in soil were analysed at 0-5, 5-10 and 10-15 cm depth. Cover crops showed to bring P up from the soil, accumulating organic P on the soil surface. Considerably higher P-efficiency (total over the nine years, as P in harvested grain / P inputs) was shown with SSP (39 – 55%) compared to rock phosphate (15 – 27%). With SSP, the P-efficiency with some cover crops was higher than fallow (48%), but was similar or lower with others. Total maize grain yield was around one third higher when P fertiliser was applied than with no-P, but was similar between SSP and rock phosphate (as tested, that is with 3 – 4 x more total P input with rock phosphate) and for the different cover crops or fallow.
“Cover Cropping May Alter Legacy Phosphorus Dynamics Under Long-Term Fertilizer Addition”, A. Soltangheisi et al., Front. Environ. Sci. 8:13 https://dx.doi.org/10.3389/fenvs.2020.00013 and “Do cover crops change the lability of phosphorus in a clayey subtropical soil under different phosphate fertilizers?”, A. Teles et al., Soil Use and Management, March 2017, 33, 34–44 https://dx.doi.org/0.1111/sum.12327
De Souza Nunes et al. report results of seventeen years of field trials in Brazil, 32 m2 plots, with 8 treatments: conventional or no-till x broadcast or furrow fertiliser application x TSP (triple super phosphate) or reactive rock phosphate (both at 35 kgP/ha/y). This reactive rock phosphate had high carbonate content, and so high P availability (44% citric acid solubility of P). Soybean and corn were cultivated. The soil initially had very low P availability and c. 1 mgP-total/kg. Results showed that broadcast fertiliser application resulted in a higher grain yield than furrow fertiliser placement. Under no-till, TSP resulted in grain yield c. 10% higher than with reactive rock phosphate, irrespective of spreading method. Under conventional tillage, TSP gave marginally higher (1-2%) yield than reactive rock phosphate for comparable spreading method. Reactive phosphate rock generally, but not consistently, led to higher accumulation of phosphorus in soil, especially calcium-associated phosphorus and particularly when broadcast.
“Distribution of Soil Phosphorus Fractions as a Function of Long-Term Soil Tillage and Phosphate Fertilization Management”, R. de Souza Front. Earth Sci. 8:350 https://dx.doi.org/10.3389/feart.2020.00350
This online event showcased 26 crop nutrition start-ups and discussed innovation from technology to market for new fertiliser approaches: biostimulants, controlled release, organic fertilisers, nutrient recycling and data solutions. This was IFA’s (International Fertilizer Association) first innovation conference and attracted over 400 registrants (220 online participants for the recycling session).
Chris Thornton, ESPP presented an overview of EU policies driving nutrient recycling and of different routes, from agricultural valorisation of sewage biosolids or processed digestate, through use of wastewater nutrients to feed biomass, to technical recovery of phosphate chemicals from ashes and other waste streams (ESPP slideshare).
Nutrient recycling
Yariv Cohen, EasyMining (RagnSells), presented the Ash2Phos process for recovery of high purity PCP (precipitated calcium phosphate) from sewage sludge incineration ash. Two full scale sites are under permitting: Helsingborg, Sweden and Gelsenwasser, Germany (both 30 000 t-ash/year, that is each around 3.5 million population wastewater), see ESPP eNews n°55. EasyMining’s objective is to be processing 300 000 t-ash/year by 2030.
Joseph Dahan, SGTech, presented their three-stage anaerobic/aerobic digestion system for manures, in which the third biological stage transfers over 60% of the phosphorus into the solid fraction (in particular as polyphosphate). Overall, methane production is increased (+25% compared to standard AD is claimed) and 80% nitrogen removal is achieved (released as N2 not as ammonia because of neutral pH operation). A pilot plant is in operation since 2018 (c. 15 000 t/y of manure from 100 cattle) and several further projects are currently in planning, both using containerised installations for smaller farms (< 200 cattle) and a possible project to treat pig manure.
Thomas Mannheim, Ductor, presented the company’s technology for anaerobic digestion of nitrogen-rich substrates like poultry or fish waste, which uses specifically selected bacteria to convert c. 60% of nitrogen to ammonia in a separate digester, upstream of the main anaerobic digester. All nutrients are converted to fertilisers: ammonia is stripped and recovered as a liquid nitrogen fertiliser, and the digestate from biomethane production is used for the production of organic NPK fertilizers. A first full scale plant (poultry litter) is operating at Juanita, Mexico, since January 2020 (0.25 MW electrical capacity) and a second one starts in June 2021 in Germany (0.5 MW). Further projects are under planning in Poland, the USA and Norway (up to 4 MW). The technology is modular, scalable, can be added to existing biogas plants or in new plants.
Organic fertilisers
Chiara Manoli, ILSA and ECOFI, summarised innovation and R&D in processed organic fertilisers. The EU market is at present around 3 million €/year and growing c. 4%/year. Organic fertilisers offer agronomic benefits including nutrient release rates adapted to plant needs, higher phosphorus uptake, and interactions between nutrients and humic substances which protect nutrients in soil from losses and stimulate soil microbial activity (see SOFIE conference summary in ESPP SCOPE Newsletter n°130). Innovation and research is today orientated to enable use of varied organic secondary materials as inputs whilst ensuring traceability, safety and predicable product quality; production technologies to improve quality and nutrient content; customised formulations for specific crops or soils; improving understanding of nutrient mineralisation, impacts on soil microbial activity and agronomic effectiveness; combinations with mineral nutrients (organo-mineral formulations) and information of farmers.
David Lebret, Innovafeed, introduced the agronomic and environmental benefits of insect frass as an organic fertiliser. Innovafeed operates two insect farms in northern France, upcycling wheat by-products to rear black soldier fly larvae, generating proteins and oil for animal nutrition as well as insect frass (a mixture of insect faeces and used substrate) for plant nutrition: Gouzeaucourt (pilot scale, capacity 1.000T/yr protein & 6.000T/yr raw frass ) and Nesle (industrial scale, 15.000T/yr protein & 50.000T/yr processed frass). Insect frass both supports plant growth (thanks to a combination of N, P and K nutrients, both rapidly and more slowly available) and stimulates soil activity (high concentration in organic matter content and presence of beneficial bacteria and chitin with biostimulation effects). See IPIFF position in ESPP eNews n°40.
Hugh MacGillivray, Anuvia, presented the company’s innovative organo-mineral fertiliser, made by fixing mineral N, S and P to amino acids using inputs such as food waste, manure, agricultural by-products and wastewater residuals. A pilot production plant has now been operating for five years (???? t/y) and a 1.2 million t/y plant is now under construction in partnership with Mosaic. The product offers controlled nutrient release: 70% N in 2-3 weeks and the remaining 30% in the following two months. Over 350 field trials show an average +5% yield compared to mineral fertilisers, and studies suggest also lower nutrient losses, plant nutrition stable over time and lower overall greenhouse emissions (-10%).
Innovation and research
Michael McLaughlin, University of Adelaide, outlined the very wide range of innovations in fertiliser technologies, both for products, in patents and research publication. These include: delivering mineral fertilisers as nanomaterials, layered double hydroxides, graphene-based materials, hydrogels, zeolites, stabilised N fertilisers, sulphur-polymer composites, metal-organic molecules, microbes and biostimulants.
Phil Pardey, University of Minnesota, summarised data since the 1970’s on global agricultural R&D spending. Developed countries have a considerably reduced share of global public spending on agriculture R&D which became particularly pronounced after 2000. Many high-income countries have also reorientated research away from productivity, e.g. towards sustainability. The share of global agricultural R&D spending by low-income countries has also shrunk, but there is substantial growth in Asia and Brazil. Agriculture R&D is increasingly privately funded and performed. Nearly ¾ of total agriculture R&D spending occurs in just 10 countries, with China accounting for over ¼ of the global total.
Biostimulants
Patrick Brown, UC-Davis, suggested that biostimulants all function by helping plants to deal with stress (i.e. increase crop system resilience), for example water stress or nutrient limitations. Environmental stress of crops is ubiquitous, so the potential value of biostimulants is significant. There are however major challenges for R&D, product development and testing, in that biostimulant effect will be related to occurrence of stress, which is unpredictable and often different stresses occur at the same time. Precision agriculture can however improve this targeting.
Manish Raizada, University of Guelph, Canada, showed that microbial biostimulants can have a range of functions, including solubilising minerals in soil such as P, K, Zn, Si so making them plant available, promoting root growth so improving fertiliser uptake, improving yield by promoting growth, combating plant pathogenic microbes. In particular, he presented developments in nitrogen fixing microbes: recent work has shown that repeated rhizobia inoculation through the growing season can increase yields of soy (a legume, which “naturally” has such nitrogen-fixing microbes), and combining rhizobia with other specific bacteria or fungi can also increase yields. There are many nitrogen-fixing rhizobia microbe products on the market.
Luca Bonini, Hello Nature, presented some crop benefits shown for the company’s peptide biostimulant. In spinach, yield was increased +8% (with nitrogen fertiliser) to +33% (no N fertiliser): the peptides are thought to act as signalling molecules, inducing nutrient uptake by the plant. In lettuce, the peptides showed to reduce yield loss caused by salinity: that is, mitigate plant stress. A biostimulant containing micro-organisms and root-stimulating peptides showed to increase both weight yield and sugar contents in melons. He underlined the need for more research and innovation into biostimulants, tailor-made to specific needs, and for field trials with different crops in different conditions, in order to provide appropriate information to farmers.
Andrea Bagnolini, Salvi Vivai (Italy’s leading fruit tree nursery), indicated that there are three types of biostimulants most used on fruit farms: to improve nutrient uptake, without increasing the use of fertilisers and respecting regulation whilst improving yield (this helped Salvi Vivai to grow the Guinness Book of Records biggest cherry in the world in 2020); to improve crop stress resilience; and to ensure uniform size of fruit, which is important for market value.
Mid-latitude peatlands are estimated to hold 0.23 Gt of phosphorus (1.7% of global soil P). A study of 23 such bogs worldwide suggests that increased atmospheric P deposition increases decomposition and reduces carbon fixation. From literature, data on P, N and C in ombrotrophic* peatlands at different depths was identified for 23 sites worldwide, with time accumulation data available for 11 of these (using radioactive dating). This data was combined with rates of P, N and C accumulation in the acrotelm** and catotelm** from a bog in Sweden. Atmospheric P deposition is the limiting nutrient for such peat bogs, limiting productivity and nitrogen fixation in the upper layers, but also limiting decomposition in the lower layers. P:N ratio in accumulated organic material in the catotelm (lower layers) is thus significantly lower than that in the acrotelm (upper layers), as P is recycled in the acrotelm. The field data show a strong positive correlation between phosphorus accumulation in the catotelm and decomposition of organic carbon, and a negative correlation between the catotelm P:N ratio and carbon burial. The authors conclude that although increased P input to such peat bogs will increase primary carbon fixation, the overall impact will be a significant reduction in the carbon burial rate, or possibly even net carbon loss. Questions are therefore raised about how much atmospheric P deposition has increased with anthropogenic activity (e.g. burning fossil fuels) compared to natural sources (desert dust, pollen …) – see ESP eNews n°43. The authors note that deposition to peat bogs will vary considerably with local sources depending on nearby soils and vegetation (dust, pollen). Further work is needed to better understand potential carbon impacts of P deposition to peat bogs at local and global scales.
* ombrotrophic (from Greek: cloud fed) = receiving water and nutrients only from rain, not runoff.
** acrotelm = living and catotelm = dead layers of a peat bog, the catotelm generally being the deeper layer or below the water table, where oxygen is not available.
“Phosphorus supply controls the long-term functioning of mid-latitude ombrotrophic peatlands”, EarthArXiv pre-review preprint 2021, D. Schillereff et al., DOI.
Five year field tests were carried out to compare animal bone char, sulphur-modified animal bone char, triple super phosphate (TSP) and control (no P fertilisers), on soils with three different initial levels of phosphorus. The bone char was purchased from Bonechar Carvao Ativado do Brasil https://www.bonechar.com.br/ and is produced by pyrolysis of animal bones at >800°C, resulting in a material with c. 12% carbon and 70 – 75 % hydroxyapatite (calcium phosphate) content, marketed since 1987 as an activated charcoal material for applications in the food industry, waste treatment, decontamination. The sulphur-modified animal bone char is treated with reduced sulphur gas compounds, e.g. H2S, according to a 2021 patent application. The field trials were carried out in Braunschweig, Lower Saxony, Germany, with a crop rotation of winter barley, winter oilseed rape, winter wheat, lupin and winter rye. In the first year, on P deficient soil, the control (zero P fertiliser) gave 90% yield compared to TSP, bone char 94%, sulphur bone char 95%. Similar significant differences in yield showed in years 3 and 4, and no significant differences between fertiliser treatments in years 2 and 5.
A second paper analyses the changes in soil bacteria related to P turnover in the field trial soils. Effects of fertilisation with animal bone char and sulphur-modified animal bone char were compared (for soils with very low, low and optimal initial P concentrations) to no P fertilisation (control) and to conventional TSP under winter wheat. Sulphur-enriched bone char addition increased the P-solubilisation potential of soil bacteria. Low soil P concentration and bone char fertilisation favoured P recycling from biomass and bacteria P-uptake systems, indicated by high abundance of bacteria with phoD or pstS genes. Bacterial P turnover was influenced by the sulphur-enriched bone char, by the plant development stage and by the initial P concentration.
“Agronomic evaluation of bone char as phosphorus fertiliser after five years of consecutive application”, K. Panten, P. Leinweber, Journal für Kulturpflanzen, 72 (12). S. 561–576, 2020, ISSN 1867-0911, DOI
“Effects of different innovative bone char based P fertilizers on bacteria catalyzing P turnover in agricultural soils”, Agriculture, Ecosystems and Environment 314 (2021) 107419, DOI.
Granulated poultry manure showed the same P fertiliser efficiency as superphosphate, but was less than half as effective after pyrolysis. N fertiliser efficiency was reduced by more than 90% after pyrolysis. Fertiliser efficiency was tested in five-month pot trials with rye grass in low-P soil, pH 6.5. Poultry manure (bedded with Sphagnum peat) was tested after granulation to 3 – 6 mm (from Biolan), after mixing with feather meal and after pyrolysis at 460°C for 90 minutes. Yield-based fertiliser efficiency was compared to mineral phosphate fertiliser (superphosphate). The granulated poultry manure showed the same P-efficiency as superphosphate (100%) over one growing season, the mixture with feather meal somewhat lower efficiency (75%) and the pyrolysed poultry manure much lower P-efficiency (45%). Soil inoculation with arbuscular mycorrhizal fungi (AMF) did not enhance the P-efficiency. In a previous paper, the N fertiliser efficiency of the pyrolysed poultry manure showed (in the same pot trials) to be only 3% that of mineral N fertiliser, compared to 45 – 50% for granulated manure.
“Bioavailability of phosphorus in granulated and pyrolyzed broiler manure”, M. Sarvi et al., Environmental Technology & Innovation 23 (2021) 101584 DOI. “Granulated broiler manure based organic fertilizers as sources of plant available nitrogen”, R. Keskinen et al., Environmental Technology & Innovation 18 (2020) 100734 DOI.
Pot trials with maize and soy conclude that blending 25% - 50% struvite with mineral P fertiliser reduces P-loss risk without restricting early-season growth. Soil pH was 5.6. Struvite (Ostara) was granule size 1.5 – 3 mm and mineral P fertiliser was MAP (mono ammonium phosphate) granule size 3 mm. Maize and soybean biomass was measured after 44-45 days. Maize showed the same biomass production with 25% or 50% struvite compared to 100% MAP. Soy showed the same biomass production with 25% struvite. Results for P-uptake were, however, very different. P-uptake was the same for up to 100% struvite with maize, but was higher with struvite than with MAP for soy . Residual soil Mehlich-3 phosphorus decreased with increasing % of struvite used, suggesting lower risks of P-losses to surface waters.
“Maize and soybean response to phosphorus fertilization with blends of struvite and monoammonium phosphate”, A. Hertzberger et al., Plant Soil 2021 DOI.
The new institute, GPI, launched by the Mohammed VI Polytechnic University, Morocco, aims to promote global, science based research and innovation and collaboration on industrial phosphorus use and nutrient stewardship. It will be led by Amit Roy, previously with IFDC and Global Traps, and has an Advisory Board chaired by the President of the Mohammed VI Polytechnic University and including representatives of the Morocco Ministry of Agriculture, the US Sustainable Phosphorus Alliance, industry experts and scientists. The GPI aims to bring together leading scientists, industry, policy makers and stakeholders, to develop inclusive dialogue and collaboration, and to create and share innovative solutions to balance the need and use of phosphorus in the production of health food, animal feed and natural fibres, in the spirit of the UN Agenda for Sustainable Development. www.tgpi.org
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ASLO (Association for the Sciences of Limnology and Oceanography) Special Session (SS06) on Methane Accumulation in Oxic Aquatic Environments: Sources, Sinks and Subsequent Fluxes to The Atmosphere. Within the 2021 Aquatic Sciences Meeting (online, 22-27 June 2021). In partnership with the Leibniz Institute of Freshwater Ecology and Inland Fisheries (IGB) and ASLO, ESPP and SPA will follow-up with a webinar to exchange between science, water stakeholders and policy makers on implications of aquatic methane emissions for nutrient management. Proposals for input are welcome.
ASLO special session on methane in oxic aquatic environments: https://www.aslo.org/2021-virtual-meeting/session-list/
7th July 2021, 10h30 - 16h30 CEST. Online conference will look at current status and future developments in phosphorus removal from wastewater, P-stewardship and P-recovery. Speakers include the UK Environment Agency, Isle Utilities, The Rivers Trust, several UK water companies, ESPP.
The European Commission has published its Zero Pollution Action Plan, part of the Green Deal, including proposed actions on nutrient loss reduction, nutrient recycling, sewage reuse, ammonia emissions as well as putting a price to pollution, actioning the polluter-pays principle and incentives for alternatives. The Plan is presented as a ”compass for including pollution prevention in all relevant EU policies”. The Zero Pollution Hierarchy is emphasised: 1) prevent pollution by clean-by-design production and the circular economy, 2) minimise releases and exposure, 3) eliminate and remediate. An emphasis is placed on stricter implementation and enforcement.
The Zero Pollution Targets for 2030 include reducing nutrient losses by 50% (specifying as compared to 2012-2015), as already set in both the Farm-to-Fork and Biodiversity Strategies (see SCOPE Newsletter n°131).
The Plan states that this will be achieved by “implementing and enforcing the relevant environmental and climate legislation in full, identifying with Member States the nutrient load reductions needed to achieve these goals, applying balanced fertilisation and sustainable nutrient management, stimulating the markets for recovered nutrients and by managing nitrogen and phosphorus better throughout their lifecycle”. It will be promoted by the Mission ‘ Soil Health and Food’, and the agricultural European Innovation Partnership (EIP AGRI). The Mission ‘Healthy oceans, seas, coastal and inland waters’ will also address nutrients.
In order to make livestock farming more sustainable, the Commission will “facilitate the placing on the market of alternative feed materials and innovative feed additives”.
The need to further reduce ammonia emissions will be assessed, in particular from intensive livestock, possibly by actions under the Common Agricultural Policy or by “making manure handling blinding”
The already engaged reviews of the Urban Waste Water Treatment and Sewage Sludge Directives will “increase the ambition level to remove nutrients from wastewater and make treated water and sludge ready for reuse, supporting more circular, less polluting farming. It will also address emerging pollutants such as microplastics and micropollutants, including pharmaceuticals”.
The announced Integrated Nutrient Management Action Plan (consultation expected later in 2021 see www.phosphorusplatform.eu/regulatory) will maximise synergies between policies and use “the green architecture of the new common agricultural policy, especially via conditionality and eco-schemes”.
The annexed list of actions includes, for 2023, to “Compile and make accessible in a digital format all main obligations on nutrient management stemming from EU law to limit the environmental footprint of farming activities”.
European Commission “Pathway to a Healthy Planet for All. EU Action Plan: 'Towards Zero Pollution for Air, Water and Soil”, SWD(2021)140 - SWD(2021)141, 12th May 2021 https://ec.europa.eu/environment/strategy/zero-pollution-action-plan_fr
Methane emissions are estimated to represent c. 20% of greenhouse impact of fossil fuels and ¾ of climate change impact of lakes and reservoirs, and are increased by eutrophication (see SCOPE Newsletter n°137). Increasing eutrophication globally could increase lake and reservoir methane emissions to 38 – 58 % of current fossil fuel greenhouse impact by 2100. Societal costs of lake and reservoir methane emissions are estimated at 7 – 80 trillion US$ (total for the years 2015 – 2050), using US Government Interagency Working Group methodology. This does not include methane emissions from rivers, coastal waters and oceans, nor does it include other aquatic greenhouse gas emissions (CO2, N2O). The methodology was applied to Lake Erie, North America, to compare estimated societal costs of eutrophication impacts on leisure fishing or on beach closures (due to harmful algae blooms). The conclusion is that societal costs of eutrophication-driven methane emissions are an order of magnitude higher than either of these local societal costs, and also higher than the estimated cost of reducing nutrient inputs to the lake by 40% by changing agricultural practices. The study notes that are not here considered other local societal costs of eutrophication, in particular loss to property value and possible health risks from toxic algae blooms, but that the climate costs of methane emissions are nonetheless a very significant societal cost of eutrophication.
“Protecting local water quality has global benefits”, J. Downing et al., Nature Communications (2021), 12:2709, DOI.
NOTE: ASLO Special Session (SS06) on Methane Accumulation in Oxic Aquatic Environments, part of the ASLO 2021 Aquatic Sciences Meeting 22-27 June 2021 online - Website
The European Commission has published its third report towards criteria for using “By-Products” as Component Materials for EU fertilising products (CMC11, additives and CMC-WW) for comment by 16th August 2021, under the new EU Fertilising Products Regulation 2019/100). The 180-page document now proposes detailed criteria for which families of by-product would be eligible, with proposed quality/purity criteria, contaminant limits, process input material exclusions, etc. This will be discussed at the EU Fertilisers Expert Group 24-25 June, at which ESPP is represented.
The following summarises ESPP’s understanding of the JRC proposal after a first reading – it may not be correct. We will try to verify whether our understanding is correct and publish an updated summary and proposed comments and input in coming weeks.
The new proposal is significantly narrower than was suggested in March this year (CMC-WW initial proposal, see ESPP eNews n°53). ESPP’s request to widen to “derivates” (see ESPP eNews n°54), that is the eligible by-products can only be included in an EU fertilising product with no further chemical processing, they cannot be used as a precursor to produce other materials (note that by-products can be used as precursors in CMC1, but not if they have “waste” status).
The new JRC proposal is somewhat complex, with four different routes:
Routes (1) and (2) are subject to the requirements that (a) the material must be a “by-product” as defined under the Waste Framework Directive 2008/98/EC, (b) Animal By-Products, polymers, compost and digestate are excluded, and (c) the material must be REACH registered (with conditions). For routes (1) and (2) a specific list of contaminant limits is defined.
(1) By-products from seven specified industrial processes: methionine, mineral ore processing (this category includes by-product gypsums and phosphogypsums), Solvay process, acetylene production, ferrous slags, specific metal treatments, humic/fulvic acids from drinking water treatment;
(2) (any) by-product used as a “technical additive” at <5% total in the final EU fertilising product.
Routes (3) and (4) are “CMC-WW High Purity Materials”, which was originally proposed in March this year (see ESPP eNews n°54). This proposal has been significantly narrowed and now covers ONLY mineral salts of ammonia, sulphur (inc. elemental sulphur), calcium carbonate or calcium oxide, subject to 95% purity and organic carbon < 0.5%. These mineral salts must also respect a detailed and extensive limits of contaminant limits, and must be REACH registered (with conditions). They can result from:
(3) any “production” process, to which inputs can be any material (chemicals, biomass, waste …) other than Animal By-Products
(4) gas purification from (to simplify): hygienised manure, livestock housing, storage of non-hygienised manure, non-hazardous wastes or any other material except Animal By-Products
European Commission JRC “Technical proposals for by-products and high purity materials as component materials for EU Fertilising Products. Interim report”, 14 June 2021 https://circabc.europa.eu/ui/group/36ec94c7-575b-44dc-a6e9-4ace02907f2f/library/785d1835-07b3-4b3c-a46a-e269a33c74c7/details
Comments are open to 16th August but can only be submitted via members of the EU Fertilisers Expert Group. Please therefore send all comments to ESPP before 16th July, in order to enable them to be taken into account.
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ASLO (Association for the Sciences of Limnology and Oceanography) Special Session (SS06) on Methane Accumulation in Oxic Aquatic Environments: Sources, Sinks and Subsequent Fluxes to The Atmosphere. Within the 2021 Aquatic Sciences Meeting (online, 22-27 June 2021). In partnership with the Leibniz Institute of Freshwater Ecology and Inland Fisheries (IGB) and ASLO, ESPP and SPA will follow-up with a webinar to exchange between science, water stakeholders and policy makers on implications of aquatic methane emissions for nutrient management. Proposals for input are welcome.
ASLO special session on methane in oxic aquatic environments: https://www.aslo.org/2021-virtual-meeting/session-list/
To contribute to the ESPP- SPA- IGB webinar: contact
7th July 2021, 10h30 - 16h30 CEST. Online conference will look at current status and future developments in phosphorus removal from wastewater, P-stewardship and P-recovery. Speakers include the UK Environment Agency, Isle Utilities, The Rivers Trust, several UK water companies, ESPP.
https://event.wwtonline.co.uk/phosphorus/
The European Commission has published its Zero Pollution Action Plan, part of the Green Deal, including proposed actions on nutrient loss reduction, nutrient recycling, sewage reuse, ammonia emissions as well as putting a price to pollution, actioning the polluter-pays principle and incentives for alternatives. The Plan is presented as a ”compass for including pollution prevention in all relevant EU policies”. The Zero Pollution Hierarchy is emphasised: 1) prevent pollution by clean-by-design production and the circular economy, 2) minimise releases and exposure, 3) eliminate and remediate. An emphasis is placed on stricter implementation and enforcement.
The Zero Pollution Targets for 2030 include reducing nutrient losses by 50% (specifying as compared to 2012-2015), as already set in both the Farm-to-Fork and Biodiversity Strategies (see SCOPE Newsletter n°131).
The Plan states that this will be achieved by “implementing and enforcing the relevant environmental and climate legislation in full, identifying with Member States the nutrient load reductions needed to achieve these goals, applying balanced fertilisation and sustainable nutrient management, stimulating the markets for recovered nutrients and by managing nitrogen and phosphorus better throughout their lifecycle”. It will be promoted by the Mission ‘ Soil Health and Food’, and the agricultural European Innovation Partnership (EIP AGRI). The Mission ‘Healthy oceans, seas, coastal and inland waters’ will also address nutrients.
In order to make livestock farming more sustainable, the Commission will “facilitate the placing on the market of alternative feed materials and innovative feed additives”.
The need to further reduce ammonia emissions will be assessed, in particular from intensive livestock, possibly by actions under the Common Agricultural Policy or by “making manure handling blinding”
The already engaged reviews of the Urban Waste Water Treatment and Sewage Sludge Directives will “increase the ambition level to remove nutrients from wastewater and make treated water and sludge ready for reuse, supporting more circular, less polluting farming. It will also address emerging pollutants such as microplastics and micropollutants, including pharmaceuticals”.
The announced Integrated Nutrient Management Action Plan (consultation expected later in 2021 see www.phosphorusplatform.eu/regulatory) will maximise synergies between policies and use “the green architecture of the new common agricultural policy, especially via conditionality and eco-schemes”.
The annexed list of actions includes, for 2023, to “Compile and make accessible in a digital format all main obligations on nutrient management stemming from EU law to limit the environmental footprint of farming activities”.
European Commission “Pathway to a Healthy Planet for All. EU Action Plan: 'Towards Zero Pollution for Air, Water and Soil”, SWD(2021)140 - SWD(2021)141, 12th May 2021 https://ec.europa.eu/environment/strategy/zero-pollution-action-plan_fr
Proposed amendments to the mandate to CEN for standards to support the new EU Fertilising Products Regulation include different standards to determine P solubility in inorganic fertilisers, and composition and contaminants in STRUBIAS materials. Standards to assess total P2O5 content, water soluble, NAC, formic acid and citrate soluble P2O5+ are requested for inorganic, organic and organo-mineral fertilisers. Standards to assess dry matter and contents of organic carbon, P2O5, iron, aluminium and several contaminants and pathogens are requested for Precipitated Phosphate Salts or their Derivates, standards for various contaminants (inc. PAH16, PCDD/F-equiv are requested for ashes/ash derived products and for biochars, as well as H/C-org for biochars.
Document for consultation https://ec.europa.eu/docsroom/documents/45687 (Draft amendment to Commission Implementing Decision C(2020) 612 final of 10.2.2020 on a standardisation request to the European Committee for Standardisation as regards the EU fertilising products in support of Regulation (EU) 2019/1009). Comments by 16/6/2021 to
A European Commission stakeholder workshop emphasised the need to address contaminants in sewage sludge (especially pharmaceuticals, microplastics, heavy metals and PFAS/PFOS) and showed support for regulatory mechanisms to support phosphorus recycling (blending obligation or % recycling requirement). The Urban Waste Water Treatment Directive (UWWTD) was evaluated in 2018, concluding “fit for purpose” but possibilities for improvements. The Sewage Sludge Directive (SSD) is currently undergoing evaluation. DG ENVI highlighted that the SSD is part of the Green Deal agenda, with objectives of climate neutrality, zero pollution and circular economy, and is cited in the EU Methane Strategy. A 2014 evaluation of the SSD concluded that it is “fit for purpose”. An aim of the current evaluation is to strengthen regulation of pollutants in sewage sludge. Two EU JRC projects were presented: modelling impacts of micropollutants in sewage sludge, assessing climate emissions impacts of UWWTD and SSD policies. Studies presented suggested that micropollutants present in sewage sludge may not pose adverse risk to soil, but that long term sludge use in agriculture led to levels of PFAS which could impact earthworms. The lack of information on microplastics was noted. The importance of source control, reducing or preventing input of contaminants into sewage where possible, was emphasised. Phosphorus and nitrogen recovery from sewage were discussed, with much stakeholder support expressed for phosphorus recycling policies such as a blending obligation (including a certain level of recycled P in fertilisers) or a % P-recycling requirement.
Trinomics, for European Commission DG Environment “Evaluation of the Sewage Sludge Directive 86/278/EEC” http://trinomics.eu/project/6515-sewage-sludge-directive-86-278-eec/
Open to 21 July 2021. This is a general public questionnaire, plus additional questions for experts and operators – you do not have to answer all questions. Questions ask what should be priorities for action (nutrients are one of seven proposed priorities), how to improve protection of nutrient “Sensitive Areas”, addressing micropollutants, circularity (proposals include recovery obligations for phosphorus and other materials).
“Water pollution – EU rules on urban wastewater treatment”, EU public consultation open to 21 July 2021.
Open to 11 August 2021. Environmental footprint of algae and environmental benefits of algae products are addressed, as are impact on CO2, nutrients capture and bioremediation. The use of algae for waste treatment (e.g. nutrient removal from wastewater, CO2 or NOx abatement), and regulatory questions around such waste-fed algae (e.g. End-of-Waste) are not addressed, but can be added in the comments boxes.
“Public consultation on the EU Algae initiative”, EU public consultation open 11 August 2021.
A modelling study concludes that ambitious but technically feasible policy actions on municipal waste water treatment and on agricultural fertilisation could reduce total EU nitrogen and phosphorus losses to surface waters by -14% and -20% respectively. The study was led by the European Commission’s Joint Research Centre. This ambitious but technically feasible scenario (MTFR = High Technically Feasible Reduction) considers that all municipal sewage works are upgraded to the highest nutrient removal level (tertiary treatment with “enhanced” phosphorus removal) and agricultural fertilisation is set to limit nitrogen surplus to 10% of N in output, and P is reduced correspondingly. The study concludes that this would “only slightly” increase proportion of surface waters in good ecological status (as defined by the Water Framework Directive). The study notes that the resulting differential reductions in N and P losses could worsen nutrient unbalances in coastal waters. ESPP considers that the study shows that technically feasible actions on sewage treatment and agricultural fertilisation can significantly reduce nutrient losses, but that this reduction is much less than the -50% nutrient loss reduction target fixed by the EU Farm-to-Fork strategy (see SCOPE Newsletter n°139) and that a combination of other measures not assessed in this study will be needed for higher nutrient loss reductions and to achieve Water Framework Directive ecological quality objectives, for example: phosphorus traps and buffer strips in fields, morphological restauration of rivers, recreation of wetlands, treatment of discharges from small settlements and isolated households, treatment of stormwaters …
“How EU policies could reduce nutrient pollution in European inland and coastal waters?”, B. Grizzetti et al., Global Environmental Change
Volume 69, July 2021, 102281 DOI.
Kemira and Ragn-Sells’ daughter company EasyMining (both ESPP members) have announced a collaboration to recover phosphorus from sewage sludge at Kemira’s industrial site in Helsingborg. This means that EasyMining takes the next step and continues with the plans to build a plant for phosphorus recycling from 30,000 t/y of sewage sludge incineration ash to be operational in 2025. The patented Ash2Phos technology from EasyMining attacks the ash with hydrochloric acid, then uses purification processes to separate out a high-grade calcium phosphate which can technically be used in fertiliser production, animal feed (see ESPP eNews n°52), or the chemicals industry, recovering more than 90% of the phosphorus contained in the ash. The process can also recover iron and aluminium present in the ash separately for e.g. recycling by Kemira as a coagulant for chemical P-removal in sewage works. The new plant will create 30 jobs within Kemira’s Helsingborg industrial park, South West Sweden. Sewage sludge ash is expected to come from Sweden but also to be imported via the site’s maritime access. The project has been granted 5 M€ from Sweden’s climate fund (Klimatklivet).
“Ragn-Sells and Kemira jointly engage in phosphorus recycling from sewage sludge” - Kemira and Ragn-Sells Newsroom
Agua DB has demonstrated a process to recover nitrate from drinking water nitrate removal, and recycle with K, S, Ca and Mg to local agriculture via fertigation. Ion-exchange is today widely used to remove nitrates from drinking water, but uses salt for regeneration. This generates a phytotoxic sodium nitrate brine, which has to be disposed, often via expensive truck transport. The Agua DB process uses water quality potash (KCl) for regeneration, instead of salt, in significantly lower quantities, so generating liquors rich in sulphate, nitrate and potassium, which can be used for fertigation in local agriculture. These can partially replace synthetic fertilisers and reduce use of potash by farmers, so reducing salination (Cl input) to farmland. A three months pilot project with Affinity Water (a UK drinking water company supplying 3.6 million people), showed effective nitrate removal down to 5 mgN/l. Red Russian Kale was grown hydroponically with the fertigation liquor providing 60% of the required nutrients, showing performance comparable to synthetic nutrients and good nutrient density in the crop. Fertigation and application of N to soil as nitrate is suggested to have agronomic benefits including improved yields with reduced fertiliser application and run-off, more efficient use of water and the potential to link irrigation water storage schemes into flood mitigation measures. The technology could also be adapted for tertiary N-removal from sewage works and can be used in industry or desalination plants.
See presentation by Mike Waite at the AquaEnviro conference “The Art of the Possible: Resource Recovery from Wastewater and Bioresources”, May 18th 2021 and presentation here from 38 minutes.
A study of an 8 ha field in SW Ontario, Canada, under maize – soy – alfalfa rotation shows that phosphorus accumulates over time in the lower parts of the field (“toe-slope” and “foot”). Soil was sampled once, in October (after harvest) at 50 sites, 10 in each of the slope classification areas (toe, foot, back, shoulder, summit). Toe and foot zones made up nearly 60% of the field area. Elevation of the field varied by about 4 m between the lowest point and the highest summit with slopes up to 15%. Results show topsoil thickness 40 - 50 % greater in foot and toe zones than in back, shoulder and summit, and mean organic carbon stock also 30 – 80 % higher. Soil Olsen-P stock showed even more pronounced accumulation in the lower parts of the field, at around 50 kg-OlsenP/ha in toe and foot zones, compared to around 20 kg/ha in summit zones. The authors conclude that soil erosion over time moves legacy P to the lower zones of the field, along with top soil, smaller soil particles and organic carbon. The study does not provide any indication as to how this local accumulation of P within the field might impact P losses to surface water.
“Spatial decoupling of legacy phosphorus in cropland: Soil erosion and deposition as a mechanism for storage”, A. VandenBygaart et al., Soil & Tillage Research 211 (2021) 105050 DOI.
A study of 18 surface water bodies in Upper Sileasia, Southern Poland, climate change will both increase nutrient losses from soils and accentuate the impact on water quality of P and N loads because of longer low-flow periods. Upper Silesia is an urbanised (4 million population) and industrialised region, with many coal mines pumping mine water into rivers. Nutrient removal is already largely installed in sewage works, and mine discharge water is expected to be reduced in the future, which will result is less dilution of nutrients. Nutrient loss from farmland was estimated as 20% of P and 50% of N in manure (based on livestock numbers) and 20% of and 88% of N applied in mineral fertilisers. Estimates of current nutrient load to the water bodies suggest that reductions of up to 90% for both P and N are needed to achieve water quality objectives, with most P and N inputs coming from agriculture in the majority of the catchments. The authors conclude that climate change will worsen nutrient-related water quality problems, by increasing agricultural losses because of extreme precipitation events and longer low-flow periods (reduced dilution). The level of nutrient removal in sewage works will not be significantly further improved, so that other measures will be necessary, targeting agriculture, treatment of fish pond discharge, landscaping and water management (which could include use of mine water to increase flows during low-flow periods).
“Impacts of nitrogen and phosphorus loads from various sources on the quality of surface water bodies in the context of climate change – case study in Poland”, A. Hamerla & B. Konczak, APP Ecology and Env Res 19(2) 1033-1048, 2021 DOI
A first-ever UN report shows that nearly 10 000 ocean Harmful Algal Blooms were recorded worldwide over 33 years, and that impacts are increasing with rising seafood demand and coastal development. 109 scientists from 35 countries analysed over 9 500 HAB events including 7 million microalgae data points, of which nearly 290 000 toxic algae species occurrences, using the Harmful Algal Event Database (HAEDAT). The widely suggested idea that blooms are increasing with climate change is not confirmed, with blooms increasing in some areas of the world and decreasing or steady in others. Increases in reported HAB events are correlated to increased monitoring and increases in perception are probably related to increased aquacultural production and coastal development. Both Europe and the Mediterranean regions show an increase trend in reported HAB events over the study period (from 1985 to 2018), but possibly with an apparent peak around the year 2000 and after that a decrease in HAB events in the Mediterranean region and fluctuations without a clear increase in Europe (see Hallegraeff et al. Fig. 3 p. 5). A large proportion of the societal impact of blooms was resulting closure of shellfish harvesting, with only rare cases of human poisoning. Economic losses caused by HABs to aquaculture are considerable, whereas in the open ocean wild fish can simply swim away from HABs. The number of recorded HABs over time was strongly correlated with intensification of aquaculture, but this is probably largely due to more intense monitoring. Data on nutrient pollution is considered inadequate to reach conclusions as what extent aquaculture contributes to causing HABs.
Report published by UNESCO (United Nations) and the Intergovernmental Panel on Harmful Algal Blooms (IOC-IPHAB, part of UNESCO’s Intergovernmental Oceanographic Commission), 8 June 2021 http://hab.ioc-unesco.org/index.php
Harmful Agal Bloom Information Portal: https://data.hais.ioc-unesco.org/
“Perceived global increase in algal blooms is attributable to intensified monitoring and emerging bloom impacts”, G. Hallegraeff et al., Nature Communications Earth & Environment (2021) 2:117 https://doi.org/10.1038/s43247-021-00178-8
Methane emissions are estimated to represent c. 20% of greenhouse impact of fossil fuels and ¾ of climate change impact of lakes and reservoirs, and are increased by eutrophication (see SCOPE Newsletter n°137). Increasing eutrophication globally could increase lake and reservoir methane emissions to 38 – 58 % of current fossil fuel greenhouse impact by 2100. Societal costs of lake and reservoir methane emissions are estimated at 7 – 80 trillion US$ (total for the years 2015 – 2050), using US Government Interagency Working Group methodology. This does not include methane emissions from rivers, coastal waters and oceans, nor does it include other aquatic greenhouse gas emissions (CO2, N2O). The methodology was applied to Lake Erie, North America, to compare estimated societal costs of eutrophication impacts on leisure fishing or on beach closures (due to harmful algae blooms). The conclusion is that societal costs of eutrophication-driven methane emissions are an order of magnitude higher than either of these local societal costs, and also higher than the estimated cost of reducing nutrient inputs to the lake by 40% by changing agricultural practices. The study notes that are not here considered other local societal costs of eutrophication, in particular loss to property value and possible health risks from toxic algae blooms, but that the climate costs of methane emissions are nonetheless a very significant societal cost of eutrophication.
“Protecting local water quality has global benefits”, J. Downing et al., Nature Communications (2021), 12:2709, DOI.
NOTE: ASLO Special Session (SS06) on Methane Accumulation in Oxic Aquatic Environments, part of the ASLO 2021 Aquatic Sciences Meeting 22-27 June 2021 online - Website
A research paper suggests that fossil fuel and livestock cap-and-trade tools, combined with a livestock / land area ratio cap, would largely ensure sustainable phosphorus use. It is suggested that resulting energy price increases would reduce P fertiliser use, despite recognising that P-fertiliser production can have negative energy consumption, because of energy used to transport and spread fertilisers. It is not however considered that transport and application of organic and recycled fertilisers may use more energy (higher bulk, decentralised logistics). Cap-and-trade of livestock products would increase price and reduce consumption, so reducing need for P-fertiliser to produce animal feeds, including imported animal feed crops. These two tools would not however address regional livestock concentration, which results in regional nutrient excesses, and geographical distribution obstacles to recycling of manure nutrients. Limiting livestock numbers per land area would avoid regional livestock concentrations and could also be used to limit total national or EU livestock production. The paper also considers limiting total P-fertiliser consumption, e.g. by a certificate trading system for mineral P fertilisers placed on the EU market.
“Economic policy instruments for sustainable phosphorus management: taking into account climate and biodiversity targets”, B. Garske & F. Ekardt, Environ Sci Eur (2021) 33-56 DOI.
A study at a site on in the UK concludes that atmospheric phosphorus deposition to coastal water in the region is “unlikely to be biologically significant”. Aerosol-derived P deposition at the study site, on Cornwall coast, South UK, between the North Atlantic and the English Channel, was estimated at 0.16 – 1.6 µ-moles-P/m2/day, estimated to be consistently below 0.1% of water P standing stock. Atmospheric nitrogen deposition, on the other hand, was estimated to be significant, at 3 – 620 µ-moles-N/m2/day, contributing up to 20% of water DIN (dissolved inorganic nitrogen) in Spring, when water DIN levels are depleted by biological uptake. The atmospheric nitrogen input is estimated to contribute to up to 22% of primary algal growth at times in Spring. The study is based on aerosol samples collected at Penlee Point Atmospheric Observatory over six months, February to July 2015, corresponding to spring algal growth.
“Inorganic nitrogen and phosphorus in Western European aerosol and the significance of dry deposition flux into stratified shelf waters”, C. White et al., Atmospheric Environment, in print 2021, DOI.
A meta-analysis of published data suggests that biochar application improves soil P availability and on plant P uptake respectively +65% and +55% on average. This is not input of P in the biochar but an impact of the biochar on the soil – crop system. The study identified 516 data pairs (from 86 studies) comparing soil P availability or crop P uptake with or without biochar application. P availability data was mostly from laboratory soil incubation tests (175 data points) and pot trials (157) with also 106 field trials, whereas crop P uptake data was mostly from field trials (80) versus 72 pot trials. The most frequently tested biochars were from crop residue and wood (total 321 P availability data points), that is biochars which would contain relatively low levels of phosphorus, versus 98 for manure biochar and only 7 for sewage sludge biochar. The mean effects of biochar on soil P availability and on plant P uptake were respectively +65% and +55%, that is higher than biochar effects on N or C reported elsewhere from biochar application. However, the data suggested that biochar showed considerably greater effects on P availability and uptake in very low phosphorus soils, acid soils (pH < 5) and in heavy textured soils. Also, effects were greater for biochars pyrolysed below 300°C. ESPP note: this temperature limit poses questions in that other studies suggest that temperatures >400°C may be necessary to remove organic pollutants and antibiotic resistance genes in pyrolysis (see ESPP eNews n°s 52 and 54)
“Could biochar amendment be a tool to improve soil availability and plant uptake of phosphorus? A meta-analysis of published experiments”, F. Tesfaye et al., Environmental Science and Pollution Research 2021 DOI.
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Murphy Ireland and Ostara have announced construction of a new Ostara Pearl® struvite recovery installation, with WASSTRIP®, as part of the upgrade of Irish Water’s Ringsend waste water treatment plant to 2.4 million p.e. capacity and conversion to biological phosphorus removal. Struvite production should start in 2023. Ringsend treats around 40% of Ireland’s wastewater and discharges into the nutrient Sensitive Area, Lower Liffey Estuary and Dublin Bay.
“Ostara and Murphy Partner to deliver part of Ringsend Wastewater Treatment Plant Upgrade Project for Irish Water”, 28th April 2021 press release.
Two significant projects to “mine” phosphate from secondary resources in Sweden were presented at the Nordic Circular Materials Conference: 21-22 April 2021. In both cases, the projects will extract phosphate from apatite minerals (phosphate rock family) present in tailings of from iron ore mining, either from operating iron production sites or from stocked tailings from closed mines. The apatite is mainly rare earth element substituted fluorapatite, e.g. monazite, low in cadmium and arsenic, and the extraction of the rare earths with the phosphate will enable economic viability.
Ulrika Håkansson, LKAB, presented the company’s project treating ore tailings from iron mines in Kiruna and Malmberget. LKAB’s objective is to be operational by 2027, producing c. 50 000 tP/year (five times Sweden’s mineral P fertiliser consumption), as apatite concentrate, and c. 30% of EU rare earth needs.
Christer Lindqvist presented the Grängesberg Apatite Recovery Project, which aims to recover apatite from stocked tailings of the Grangesberg iron mine (John Matts dam), which was the world’s biggest iron ore producer in the nineteenth century. The following rare earth elements will be produced: Y, La, Ce, Pr, Nd, Tb, Eu. Production will be around 13 000 tP/y, with the aim of starting within 3-4 years. The stocked tailings will support around seven years production, and this may be extended with a project to re-open the iron ore mine
Slides from Nordic Circular Materials Conference
LKAB secondary P-mining project: www.ree-map.com
Grängesberg Exploration Holding AB https://grangesbergexploration.se/
A review of around 100 scientific publications concludes that eutrophication significantly increases greenhouse gas emissions from freshwaters (CO2, methane, N2O). An increase of 5 µg/l of chlorophyll-a in lakes and reservoirs worldwide would result in an increase of GHG emissions equivalent to >6% of fossil fuel CO2.
The current GHG emissions from freshwaters worldwide are estimated to be equivalent to >30% of global fossil fuel CO2 emissions (56% from freshwater CO2 release, 40% from methane, 4% from N2O).
Eutrophic shallow lakes are estimated to emit nearly 50% more methane than comparable non-eutrophic lakes. Eutrophication increases organic matter production in fresh waters, but it is unclear whether the resulting net CO2 uptake will compensate for increased methane production, because the organic matter produced is readily degradable. Increased nitrogen loading to surface waters can cause them to shift from being N2O sinks to net N2O emitters. Eutrophication also increases freshwater GHG emissions indirectly, for example, by shifting from vegetation dominated by macrophytes to algae, whereas macrophyte roots tend to reduce methane production by moving oxygen to sediments. Also, cyanobacteria readily produce methane even in the oxic water zone, both at day and at night.
The review also shows that climate change is expected to significantly increase freshwater GHG emissions and eutrophication (see also ESPP SCOPE Newsletter n°137 on climate change and eutrophication), with positive feedback loops. Increasing temperatures will increase release of nutrients from sediments (accelerated mineralisation), as will extreme climate events (remobilisation of sediments). Both will also lead to increased nutrient losses from land to freshwaters. Increased temperatures may also favour methane production in freshwaters, rather than methane consumption.
This review confirms that policy makers need to further reduce nutrient inputs to surface waters, both because climate change will increase eutrophication risks, and because freshwater eutrophication contributes significantly to greenhouse gas emissions.
“The role of freshwater eutrophication in greenhouse gas emissions: A review”, Y. Li et al., Science of the Total Environment 768 (2021) 144582 https://doi.org/10.1016/j.scitotenv.2020.144582
Some 280 participants took part in the EBA – ECN webinar on 28th April.
David Wilken, German Biogas Association, presented conclusions of the EBA – ECN European survey on perspectives for CE-marking of compost and biogas under the EU Fertilising Products Regulation (FPR), when it enters into implementation in July 2022. The survey received over 100 answers from 21 countries. A large majority of respondents considered that the future CE-mark will be relevant for composts and digestates, in particular as a route to obtaining End-of-Waste status and better marketability, although many do not expect it to bring higher sales revenue and most expect it to involve significant administrative burdens and costs (in particular for conformity assessment). Most respondents consider that digestate will need some process of upgrading to achieve FPR criteria (CMC5), e.g. composting of digestate, drying, liquid/solid separation. Manure is seen as a very relevant input material, as well as sewage sludge (which is however excluded from EU FPR composts and digestates), as well as a wide range of other materials.
Theodora Nikolakopoulou, DG GROW, addressed a range of questions concerning application of the FPR to composts and digestates : manures and animal-by products as inputs – do they have to be pasteurised upstream of composting/digestion?; multiplication of conformity assessments if one compost producer supplies several fertiliser producers; definition of “sludge”; additives used upstream of the digestion process (e.g. flocculation agents) – must be declared as a distinct CMC; demonstrating conformity to PAH limits – does not necessarily mean testing …
Digestate valorisation under the EU Fertilising Products Regulation, webinar, 28 April 2021 here. Links to slides and conference report.
Open to 21 July 2021. The consultation document notes that the 2019 evaluation of the 1991 UWWTD concluded that it is largely fit for purpose, but some aspects need to be improved, and updates should align with Green Deal environment and climate objectives. The consultation is a general public questionnaire, plus additional questions for experts and operators – you do not have to answer all questions. General questions ask what you see as important risks from municipal wastewater, key mitigation actions, priorities for action (nutrients are one of seven proposed priorities), how to improve protection of nutrient “Sensitive Areas”, addressing micropollutants, circularity (proposals include recovery obligations for phosphorus and other materials).
In particular, the question (p32 of the questionnaire in PDF) “How appropriate are the following proposed measures for building a more circular waste water treatment sector?” offers the option “Setting minimum levels for recovering phosphorous and other materials” (please NOTE: ‘5’ = important). ESPP will propose, under comments to this question, to Include materials from wastewater as a priority stream for development of EU End-of-Waste criteria under the Circular Economy Action Plan.
“Water pollution – EU rules on urban wastewater treatment”, Eu public consultation open to 21 July 2021.
The 4th European Sustainable Phosphorus Conference (ESPC4) is postponed (because of Covid). New dates are 20-22 June 2022 in Vienna.
Updates: see www.phosphorusplatform.eu and https://phosphorusplatform.eu/espc4
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Online, 2nd June 2021
Event web page: www.phosphorusplatform.eu/PERM4
Registration: https://us02web.zoom.us/meeting/register/tZ0qcOmrrjouEtRlibbtiMrcZVSKb4MEvYyc
One day conference on resource recovery from wastewaters and biosolids, covering nutrient recovery, hydrogen and other materials: experience from pilot and full scale plants; market pull, user confidence and business models, regulatory framework, links to net zero carbon 2030 agenda for the UK wastewater industry.
“The Art of the Possible: Resource Recovery from Wastewater and Bioresources”, May 18th 2021 online https://conferences.aquaenviro.co.uk/events/conferences/resource-recovery-from-wastewater/
Webinar “Enabling a Circular Economy: How to encourage a viable agricultural market for nutrients recovered from biowaste”, with William Neale, Advisor, European Commission DG Environment, Jan Huitema, Member of the European Parliament, Ludwig Hermann, Proman and ESPP President, Oscar Schoumans, Wageningen University and Research, Annabelle Williams, European Landowners Association.
SYSTEMIC (Horizon 2020 project) webinar, Thursday 27th May: 13h30-15h30 CEST Registration
This meeting, co-organised by ESPP, Biorefine Cluster Europe and ETA Renewable Energies, will link science, industry, agriculture and policy makers. EU-funded projects on nutrient sustainability and phosphorus recycling (Horizon2020, Interreg, LIFE…) and national and company nutrient projects will present, enabling dialogue and synergies. PERM will address how to improve uptake of project recommendations by policy makers and users, through to market, and identify perspectives for research and policy, and implementation gaps.
In parallel to PERM, ESPP is updating our online ‘inventory’ of nutrient-related R&D projects here.
PERM4 – online – 2nd June 2021: event website: www.phosphorusplatform.eu/PERM4
Registration: https://us02web.zoom.us/meeting/register/tZ0qcOmrrjouEtRlibbtiMrcZVSKb4MEvYyc
Proposals are welcome for presentations of studies into what factors in nutrient R&D projects improve uptake of conclusions by policy makers, industry and users.
If you wish your project to be included in the programme and/or added to the inventory of nutrient R&D projects, please contact
The global fertiliser industry (International Fertilizer Association) “Smart & Green” conference will bring together scientists, industry and start-up technologies around controlled-release and stabilised fertilisers, biostimulants, incentivising and funding fertiliser innovation, digital fertiliser management, organic fertilisers and nutrient recycling.
IFA Smart & Green “where tech meets plant nutrition”, 8-10 June, online here.
ASLO (Association for the Sciences of Limnology and Oceanography) Special Session (SS06) on Methane Accumulation in Oxic Aquatic Environments: Sources, Sinks and Subsequent Fluxes to The Atmosphere. Within the 2021 Aquatic Sciences Meeting (online, 22-27 June 2021). In partnership with the Leibniz Institute of Freshwater Ecology and Inland Fisheries (IGB) and ASLO, ESPP and SPA will follow-up with a webinar to exchange between science, water stakeholders and policy makers on implications of aquatic methane emissions for nutrient management. Proposals for input are welcome.
ASLO special session on methane in oxic aquatic environments: https://www.aslo.org/2021-virtual-meeting/session-list/
Contact Mina Bizic
To contribute to the ESPP- SPA- IGB webinar: contact
The 4th European Sustainable Phosphorus Conference (ESPC4) is postponed (because of Covid). New dates are 20-22 June 2022 in Vienna. PERM, the European Phosphorus Research Meeting will be held virtually 2nd June 2021, see below.
Updates: see www.phosphorusplatform.eu and https://phosphorusplatform.eu/espc4
Open to 21 July 2021. The consultation document notes that the 2019 evaluation of the 1991 UWWTD concluded that it is largely fit for purpose, but some aspects need to be improved, and updates should align with Green Deal environment and climate objectives. The consultation is a general public questionnaire, plus additional questions for experts and operators – you do not have to answer all questions. General questions ask what you see as important risks from municipal wastewater, key mitigation actions, priorities for action (nutrients are one of seven proposed priorities), how to improve protection of nutrient “Sensitive Areas”, addressing micropollutants, circularity (proposals include recovery obligations for phosphorus and other materials).
In particular, the question (p32 of the questionnaire in PDF) “How appropriate are the following proposed measures for building a more circular waste water treatment sector?” offers the option “Setting minimum levels for recovering phosphorous and other materials” (please NOTE: ‘5’ = important). ESPP will propose, under comments to this question, to Include materials from wastewater as a priority stream for development of EU End-of-Waste criteria under the Circular Economy Action Plan.
“Water pollution – EU rules on urban wastewater treatment”, Eu public consultation open to 21 July 2021.
Over 120 (to date) industry and public water operator federations, companies and research institutes, have signed a joint letter to the European Commission requesting that materials recovered from wastewaters be included in the priority streams for development of EU End-of-Waste criteria, currently being defined under the EU Circular Economy Action Plan. Further organisations are still welcome to join this initiative and sign the letter (see below).
Recycled materials suggested include algae or plant biomass grown using wastewater; fibres, fatty acids, proteins, gums, fats and oils; phosphates and other chemicals or minerals for industrial applications (the route to EU End-of-Waste status for fertiliser applications already exists via the EU Fertilising Products Regulation); CO2; grit and sand. The request was initiated by ESPP and signatories to date include Eureau (European Federation of National Associations of Water Services), Aqua Publica Europea (European Association of Public Water Operators), EABA (European Algae Biomass Association), Biorefine Cluster Europe, Water Alliance Netherlands, AquaMinerals BV, ACR+ (Association of Cities and Regions for sustainable Resource management) …
Further signatory organisations are welcome: contact
The joint letter can be consulted here: www.phosphorusplatform.eu/regulatory
The final report (Task 2) to the European Commission for preparation of the new working plan for the Ecodesign Directive proposes as a new horizontal Ecodesign initiative “Scarce materials and critical raw materials”, because “very relevant in relation to the circular economy action plan and also in relation to the individual product’s lifecycle”.
Phosphate Rock, which is on the EU Critical Raw Materials list, is identified to have “High EHP” (Environmental Hazard Potentials). This is based on Dehoust et al. 2020 (UBA report).
Dehoust classifies Phosphate Rock as medium concern for governance, but high impact for global material and energy flow and for aggregated Environmental Hazard Potentials. The latter is based on suggested medium EHP for heavy metals, accidental hazards due to landslides etc, water stress and deserts, protected areas and governance, but high for association with radioactivity, surface mining and use of chemicals in processing (acids, flotation). This seems to indicate in some cases misinformation, for example acid used in processing phosphate rock is systematically a by-product. The report concludes that Phosphate Rock is “environmentally critical”.
The EU Critical Raw Material “Phosphorus”, that is P4, is not considered in the Ecodesign report, which is inappropriate in that P4 and P4-derivatives are essential for e.g. electronics manufacture and plastics fire safety, both of which are necessary for many energy using products addressed by EU Ecodesign criteria. This may be because “Phosphorus” (P4) is not considered in the Dehoust / UBA document.
Task 2 “Identification of product groups and horizontal measures”, final draft, March 2021.
Task 3 “Preliminary analysis of product groups and horizontal initiatives”, “Scarce and environmentally critical raw materials”, draft, February 2021.
https://www.ecodesignworkingplan20-24.eu/
“Environmental Criticality of Raw Materials, An assessment of environmental hazard potentials of raw materials from mining and recommendations for an ecological raw materials policy”, G. Dehoust et al., UBA TEXTE 80/2020 https://www.umweltbundesamt.de/sites/default/files/medien/1410/publikationen/2020-06-17_texte_80-2020_oekoressii_environmentalcriticality-report_.pdf
A stakeholder workshop organised for the European Commission (20-21 April, online, over 270 participants) addressed the revision of the EU Sewage Sludge Directive (SSD) 86/278/EEC. The European Commission, DG Environment, explained that the objectives of this Directive, in the 1980’s, were to encourage the recycling of sewage sludge to agriculture and to ensure safety. The 2014 evaluation of the SSD here concluded that it is effective in returning carbon to soil, but inadequate for promoting the Circular Economy, or for controlling pollutants other than heavy metals, and that a number of Member States have today stricter rules. The 2019 evaluation of the Urban Waste Water Treatment Directive concluded that better account should be taken of energy use and greenhouse emissions related to wastewater treatment, and that materials recovery and safe use should be promoted by the SSD. The revision of the SSD should also take into account the EU soil and pharmaceuticals strategies.
Workshop presentations included:
Workshop conclusions, after breakout sessions, suggested that safe reuse of sewage biosolids in agriculture and recovery of secondary raw materials remain Circular Economy priorities, conform to Green Deal objectives, with possibilities also for biosolids reuse in land reclamation, for which standards should be defined. A priority is reduction of contaminants at source. There is a high potential to reduce greenhouse gas emissions in wastewater treatment, with questions on how and where to define greenhouse emissions objectives.
Possible policy measures proposed include permitting of emissions to sewers of sectors such as car-washes or hair salons, tracking contaminants to source, chemicals and product policies to avoid pollution at source, minimum recovery requirements for phosphorus and for other materials, and water reuse.
European Commission Sewage Sludge Directive web page and evaluation web page.
The EU Animal Feed Regulation 767/2009 (art. 6(1) and annex II $1 and $5) excludes materials derived from wastewaters or manures irrespective of treatment or processing. Interpretation of this could pose problems for several recycling routes. For example, if phosphoric acid is recovered from sewage sludge incineration ash, it could be considered that this should not be placed on the commodity chemicals market or only with traceability indicating “not to be used in production of animal feed”.
ESPP has consulted operators and identified three relevant recycling routes, and has proposed to the European Commission to address these appropriately in order to lift potential obstacles to the Circular Economy:
ESPP’s letter is supported by a table detailing relevant processes, uses of recovered products, status of implementation and safety questions. Comments and input are welcome.
ESPP letter to the European Commission (DG SANTE), 7th May 2021, and supporting table: www.phosphorusplatform.eu/regulatory
The European Parliament has voted a resolution on the new EU Circular Economy Action Plan. Parliament calls for binding EU targets to reduce material and consumption footprints and harmonised circularity indicators. Parliament calls for investigation of the sources, fate and effects of micro-plastics in wastewater treatment and for equipping new washing machines with microfibre filters. For the Key Product Value Chain “Food, Water and Nutrients”, Parliament calls for action to reduce food waste, separate collection of bio-waste, increased replacement of fossil materials with renewable bio-based materials, measures to close the agricultural nutrient loop, reduction of EU dependency on imported vegetable protein for animal feed and increased recycling of animal manure and other organic nutrients. Parliament calls for a circular approach in waste water treatment and “highlights that resources can be recovered from wastewater, ranging from cellulose via bioplastics to nutrients, energy and water”.
European Parliament, 10th February 2021, resolution P9_TA(2021)0040 on the New Circular Economy Action Plan https://www.europarl.europa.eu/doceo/document/TA-9-2021-02-10_EN.html
Some 280 participants took part in the EBA – ECN webinar on 28th April.
David Wilken, German Biogas Association, presented conclusions of the EBA – ECN European survey on perspectives for CE-marking of compost and biogas under the EU Fertilising Products Regulation (FPR), when it enters into implementation in July 2022. The survey received over 100 answers from 21 countries. A large majority of respondents considered that the future CE-mark will be relevant for composts and digestates, in particular as a route to obtaining End-of-Waste status and better marketability, although many do not expect it to bring higher sales revenue and most expect it to involve significant administrative burdens and costs (in particular for conformity assessment). Most respondents consider that digestate will need some process of upgrading to achieve FPR criteria (CMC5), e.g. composting of digestate, drying, liquid/solid separation. Manure is seen as a very relevant input material, as well as sewage sludge (which is however excluded from EU FPR composts and digestates), as well as a wide range of other materials.
Theodora Nikolakopoulou, DG GROW, addressed a range of questions concerning application of the FPR to composts and digestates : manures and animal-by products as inputs – do they have to be pasteurised upstream of composting/digestion?; multiplication of conformity assessments if one compost producer supplies several fertiliser producers; definition of “sludge”; additives used upstream of the digestion process (e.g. flocculation agents) – must be declared as a distinct CMC; demonstrating conformity to PAH limits – does not necessarily mean testing …
Digestate valorisation under the EU Fertilising Products Regulation, webinar, 28 April 2021 here. Links to slides and conference report.
As indicated I ESPP eNews n°53, the European Commission has proposed a new Component Material Category for the EU Fertilising Products Regulation, “CMC-WW”, open to any by-product coming from a “production process” or from a gas processing / gas emissions control process” which offers “high purity” and does not contain specified contaminants. ESPP has input proposals suggesting that:
ESPP submitted list of possible candidate materials for CMC-WW, collated from stakeholders, including: ammonium and sulphur compounds from gas cleaning, sulphur from oil refining, wax by-products, spent acids, ammonium salts from fire extinguisher refurbishment, mineral salts from waste incinerator ashes, by-products from drinking water production, PHBV from fatty acid fermentation, vivianite, nutrient residues from wood bioethanol production …
ESPP proposals to the European Commission on CMC-WW for by-products in the EU Fertilising Products Regulation www.phosphorusplatform.eu/regulatory
The French Government seems to be proposing a new legal status for composts and digestates containing sewage biosolids, manure, biowaste, etc. fulfilling the AFNOR NFU 44 095 standard (that is recognition as a French ‘national’ fertiliser product). These organic fertilisers would have “Waste” (not “Product”) status, but could be placed on the market and would NOT be subject to a spreading plan (the producer is responsible “until they are used by the farmer”).
The proposed decree would establish three categories A1 (“Product”), A2 = all composts and digestates containing sewage sludge, manure, food waste, etc (“Waste”, but not subject to waste spreading plan) and B (“Waste”, subject to spreading plan).
The official Opinion of the French national agency for health, food, environment etc. (ANSES) states that “the concept of these three categories is not intuitive and their appropriation is not immediate and the whole decree has to be read to understand the distinction” (20 pages!).
It is unclear to ESPP whether this “half-waste” status (waste, but not subject to waste management plan) is conform to European regulation (Waste Framework Directive). Also, if the producer responsibility stops when the A2 materials are spread on a field, given that they are spread as a “waste”, presumably the legal responsibility is transferred to each farmer, which is unlikely to be welcome.
After consultation of stakeholders and operators, ESPP has written to the European Commission (SANTE and GROW) proposing approaches to the currently outstanding question of use of manure or other Animal By Products (ABPs) in “STRUBIAS” materials under the EU Fertilising Products Regulation (FPR), that is struvite and precipitated phosphates, ash-derived materials, pyrolysis and biochars.
The technically-finalised “STRUBIAS” criteria authorise the use of certain ABPs (inc. manure) as inputs for the three STRUBIAS categories, but only if ABP End Point “has been determined”. In order to move this forward, ESPP proposes:
ESPP letter to the European Commission on “Animal By Product End Points for EU Fertilising Products Regulation STRUBIAS materials”, 16th April 2021 www.phosphorusplatform.eu/regulatory
STRUBIAS criteria, as published for the public consultation February 2021
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12136-Pyrolysis-and-gasification-materials-in-EU-fertilising-products
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12162-Thermal-oxidation-materials-and-derivates-in-EU-fertilising-products
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12163-Precipitated-phosphate-salts-and-derivates-in-EU-fertilising-products
Up to 1.8 billion litres of polluted water are being released from a disused phosphate fertiliser factory’s 31 ha phosphogypsum pond, at Piney Point, near Tampa, Florida. The State Governor has declared a state of emergency and evacuated 300 households because the pond walls risk collapse, after starting to leak. The fertiliser factory was operated from 1966 to 1999. Media reports suggest that problems with the pond walls have been known for nearly 20 years. The water released from the pond contains phosphorus and nitrogen which will contribute to eutrophication of Tampa Bay and environmental NGOs have warned of risks of red tide algal blooms. The phosphogypsum in the pond also contains radioactive elements, but the Florida authorities say that levels in released water meet quality standards.
The Guardian UK, 4th April 2021, and other media online.
Two significant projects to “mine” phosphate from secondary resources in Sweden were presented at the Nordic Circular Materials Conference: 21-22 April 2021. In both cases, the projects will extract phosphate from apatite minerals (phosphate rock family) present in tailings of from iron ore mining, either from operating iron production sites or from stocked tailings from closed mines. The apatite is mainly rare earth element substituted fluorapatite, e.g. monazite, low in cadmium and arsenic, and the extraction of the rare earths with the phosphate will enable economic viability.
Ulrika Håkansson, LKAB, presented the company’s project treating ore tailings from iron mines in Kiruna and Malmberget. LKAB’s objective is to be operational by 2027, producing c. 50 000 tP/year (five times Sweden’s mineral P fertiliser consumption), as apatite concentrate, and c. 30% of EU rare earth needs.
Christer Lindqvist presented the Grängesberg Apatite Recovery Project, which aims to recover apatite from stocked tailings of the Grangesberg iron mine (John Matts dam), which was the world’s biggest iron ore producer in the nineteenth century. The following rare earth elements will be produced: Y, La, Ce, Pr, Nd, Tb, Eu. Production will be around 13 000 tP/y, with the aim of starting within 3-4 years. The stocked tailings will support around seven years production, and this may be extended with a project to re-open the iron ore mine
Slides from Nordic Circular Materials Conference
LKAB secondary P-mining project: www.ree-map.com
Grängesberg Exploration Holding AB https://grangesbergexploration.se/
Murphy Ireland and Ostara have announced construction of a new Ostara Pearl® struvite recovery installation, with WASSTRIP®, as part of the upgrade of Irish Water’s Ringsend waste water treatment plant to 2.4 million p.e. capacity and conversion to biological phosphorus removal. Struvite production should start in 2023. Ringsend treats around 40% of Ireland’s wastewater and discharges into the nutrient Sensitive Area, Lower Liffey Estuary and Dublin Bay.
“Ostara and Murphy Partner to deliver part of Ringsend Wastewater Treatment Plant Upgrade Project for Irish Water”, 28th April 2021 press release.
An article by Ostara in World Fertilizer provides an accessible summary of different benefits of recycling phosphorus from sewage as struvite, as operational with 22 commercial Ostara reactors running worldwide. The paper outlines the Planetary Boundary challenge for phosphorus and summarises environmental footprint study data comparing recovered struvite to production of mineral phosphate fertiliser (“emergy” approach, see ESPP eNews 35). Agronomic benefits of struvite are also outlined. Because struvite is crop-available (soluble in weak organic acids) but it is not water soluble, there is no risk of burning germinating crops, lower osmotic stress on soil micro-organisms, and reduced risks of phosphorus run-off to surface waters. Trials have shown that a combination of struvite and mineral fertiliser can increase yield and crop quality in potatoes, above standard fertiliser practice.
“Greener Cycle”, R. Leatherwood & R. van Springelen, Ostara, World Fertilizer, March 2021 http://bit.ly/3vf9ZFG
“Phosphates 2021”, the only annual global event for the phosphate mining, processing, phosphorus chemicals and phosphate fertiliser industries, brought together some 560 delegates, online, 23-25 March 2021. The online format increased attendance by +50% compared to previous physical conferences.
https://www.phosphates2021.com/
Chris Lawson and Glen Kurokawa of CRU outlined current world market trends for phosphates. After falling from around 2012 to end 2019, prices have risen rapidly since 2020, and are back to their 2012 levels (but still less than half the peak prices reached in 2008-2009). This recent increase mirrors increases in agricultural crop prices, and is driven by high world phosphorus demand (including in China, despite a long-term trend to better P efficiency here), low stocks, Covid supply disruption and specific impacts of new import tariffs for the USA.
CRU consider however that the current price level will not be sustained because increases in production (e.g. in China) will bring prices down somewhat in the coming year.
Over the next five years, significant increases in capacity will come online, e.g. in Morocco. Nonetheless prices are expected to remain high over this period because of continuing global demand and increasing costs of raw materials, wages, and (in China) environmental restoration measures.
Over coming decades, the phosphate market is expected to be impacted by long-term trends including continuing growth in agricultural demand, and circular economy initiatives (especially in Europe) to develop recycled products.
Johanna Bernsel, European Commission DG GROW, explained that the new regulation is very ambitious, widening to cover many different products related to nutrient use in agriculture, including biostimulants which can improve fertiliser nutrient use efficiency. The regulation has Circular Economy objectives, opening the European market for both recycled nutrient materials and recycling technology providers. It will also bring new protection to EU consumers, because for the first time contaminant limits are introduced for CE fertilisers, including for cadmium.
It is important to note that when the new Regulation enters into implementation in June 2022, producers will no longer be able to market under the old regulation 2003/2003, but will have the choice of using the new regulation (CE-Mark) and/or selling under national fertiliser regulations, which will remain in force in each Member State (“Optional Harmonisation”).
Producers should refer to the Frequently Asked Questions and to the Labelling Guidance, both of which documents provide important clarifications on implementation of the new regulation.
In questions from conference participants, it was clarified that the new regulation will limit cadmium to 60 mgCd/kgP2O5 in all CE-Mark mineral phosphate fertilisers from June 2022, as well as limits on certain other heavy metals, and that producers have the option to label “Low Cadmium” when below 20. However, the Commission is mandated by the regulation to review the cadmium limit by 2026, and also to assess a possible uranium limit. Johanna Bernsel also underlined that possible action is also envisaged on contaminants in all fertilisers (organic and mineral, CE-Mark or national fertilisers) with a study underway (see ESPP eNews n°52.
European Commission FRP “Frequently Asked Questions” here
European Commission FRP labelling guidance document C(2021)726 (18/2/2021) and Annex here
Konstantin Golambek, Fertilizers Europe, presented latest conclusions from the federation’s annual analysis of European fertiliser markets and estimates for trends for the coming decade. Phosphorus consumption in mineral fertilisers has fallen by around half in Europe since the 1980’s and has been fairly stable since the late 2000’s. Fertilizers Europe estimates that P use in mineral fertilisers in Europe will fall very slightly, maybe c. 2%, over the next ten years, and N by maybe -5 to -6%. However, there are major regional differences in mineral P fertiliser use across Europe, partly related to differences in density of livestock production (and so manure availability and use).
Fertiliser use will be influenced by crop choice, by climate and by the global agri-food commodity market, by innovation in agriculture, by regulation and also in the long term by a move towards more plant-based diets and by the need for the EU to replace imported animal feedstuffs, such as soy. Farmers in Europe are under high pressure because of labour costs, food industry purchasing and regulation.
Fertilizers Europe sees as key to responding to these challenges: balancing all nutrients and use of both mineral and organic fertilisers, adapting to different regional contexts, increasing knowledge per hectare, Circular Economy and high-efficiency fertilisers. The aim is to improve Nutrient Use Efficiency and maintain soil fertility. Nutrient Management Plans in the Common Agricultural Policy will be critical for this.
Chris Thornton, ESPP, summarised European policies and regulations which will significantly impact phosphorus use in Europe in coming years. The Green Deal Farm-to-Fork and Biodiversity Strategy target to reduce nutrient losses by 50% by 2030 should considerably impact use of mineral fertilisers, organic fertilisers and livestock manure. This is driven by the ongoing problem of eutrophication, likely to be accentuated by climate change, with phosphorus the main (non-morphological) cause of failure to achieve Water Framework Directive quality status requirements in surface waters. Farm-to-Fork also announces actions to promote a shift towards healthy and sustainable diets, with more plant-based foods and less red meat. However, these objectives require clear requirements on balanced nutrient management in the European Common Agricultural Policy (CAP), and this is not yet defined. Other EU policies which significantly impact phosphorus use include the confirmed inclusion of both phosphate rock and P4 on the EU Critical Raw Materials List, the EFSA safe limit (ADI) for phosphorus in food (2019) and Circular Economy policies.
ESPP presentation slides here: https://www.slideshare.net/NutrientPlatform
Yariv Cohen, Sara Stiernström and Christian Kabbe presented the EasyMining (a subsidiary of Ragn-Sells) Ash2Phos process for recovering phosphorus in a purified form from sewage sludge incineration ash. The process uses acid then lime to extract phosphorus from ash and separate off the inert silica (as a sand, useable in the construction industry). The phosphorus is purified (>96% removal of impurities including heavy metals) to produce a precipitated calcium phosphorus (PCP) which is for example 80% soluble in NAC (conform to the new EU Fertilising Products Regulation requirement of >75%) or can be converted to di-calcium phosphate (DCP, 100% NAC soluble). Iron and aluminium can be recovered and recycled as coagulants for sewage treatment. Because of the purity of the recovered PCP, this is currently being trialled for use in animal feed (see ESPP eNews n°52). Easymining today have a 30 000 t-ash/year plant currently in the permitting process in Helsingborg, Sweden, a second 30 000 t-ash/y plant under planning near Berlin Germany and aim to have a third 300 000 t-ash/year capacity in Germany within a decade.
http://easymining.se/ and ESPP – DPP – NNP P-recovery Technology Catalogue
http://www.phosphorusplatform.eu/p-recovery-technology-inventory
Jan Kirchhof, Glatt Ingenieurtechnik GmbH, presented this process which is based on suspension and granulation technologies. Ash is mixed with phosphoric or other acid or additives in a batch reactor, then buffered, then goes to a continuous spray granulation process. The processing is flexible, and other acids or solid or liquid raw materials can be used. At present, the process transfers all contaminants, inert materials such a silica, and iron and aluminium, present in the ash, into the final product. This means that at present only ashes which themselves fulfil fertiliser regulation requirements can be used. Glatt indicate that they are currently at the design phase for a process for heavy metal removal. A first full-scale plant is currently under commissioning in Haldensleben, Germany, with capacity to intake c. 30 000 t-ash per year and produce c. 60 000 t/y fertiliser.
https://phos4green.glatt.com/ and ESPP – DPP – NNP P-recovery Technology Catalogue
http://www.phosphorusplatform.eu/p-recovery-technology-inventory
Marc Sonveaux and Hadrien Leruth, Prayon, presented Prayon’s phosphoric acid production processes, including from low-grade phosphate rock and for phosphorus recycling. The Ecophos / Technophos process produces feed grade DCP (di calcium phosphate) from low-grade phosphate rock with high magnesium content (P content ≥ 5%P) using hydrochloric acid. After acid digestion of the rock, calcium carbonate is added to precipitate impurities (fluoride, silicates (>95% removal), clays, iron and aluminium (>90% removal) and heavy metals), generating 0.3 - 0.45 tDM residue cake per tonne of rock input (depending on the rock composition). After processing to DCP, fluoride is well below 2000 ppm, cadmium below detection limit, arsenic < 3 ppm, etc. The DCP is di-hydrate, offering high biodigestibility. A 5 t/day rock input pilot has been tested for up to 10 days continuous (24/24) operation in Varna, Bulgaria (see ESPP SCOPE Newsletter n°120). Prayon today has a portfolio of five conventional processes to produce phosphoric acid from phosphate rock using sulphuric acid, as well as the Ecophos/Technophos process, and the GetMoreP process. Currently technologies including H2SO4/HCl based and phosphoric acid based processes from Ecophos, aiming to recover phosphorus from sewage sludge incineration ash and other waste ashes, are at the pilot stage phase (see ESPP SCOPE Newsletter n°138)
Roy Movsowitz, Tenova Bateman Technologies, presented the TAT PPA process to produce phosphoric acid from low-grade phosphate rock (as low as 10% P) using hydrochloric acid (excess from the ChlorAlkali process). Two solvent extraction circuits, both with several stages, are required to removal calcium, sulphate and some iron, then to remove further iron and heavy metals, followed by post-treatment to remove organics, reduce fluorine and finally concentrate the phosphoric acid. Further challenges are treatment of liquid effluent (after lime neutralisation) and solid waste. A 21 000 tP2O5/y output plant is being commissioned in India and a second of the same capacity is in the construction stage.
Willem Schipper summarised uses and perspectives for P4 and its derivatives, which represent around 2% of world phosphate rock consumption (of which around half in the herbicide glyphosate). Although this is a relatively small quantity, many uses of P4 are critical and non-substitutable, including in lithium-ion batteries, fire safety, matches and pyrotechnics, catalysis, lubricants … as well as thermal phosphoric acid for electronics applications requiring very high purity. Today there are around forty P4 furnaces operating worldwide, mostly in China (maybe 30 plants, c. 70% of world production), Vietnam (8 plants, c. 10%), USA (1 plant, c. 10%) and Kazakhstan (1 Plant, c. 10%). Prices were stable in 2020, with no large new applications foreseen, and a significant part of China’s production of P4 still going to uses such as detergents or food phosphates where P4 derivatives can today be replaced by chemicals from purified “wet acid” route phosphoric acid. The market outlook is mixed, with on the one hand a new P4 production plant coming onstream shortly in Malaysia and expansions in capacity of “wet acid” purification also underway, but on the other hand growth in uses. For more information on P4 and P4 derivates, see ESPP SCOPE Newsletter n°136.
Willem Schipper also provided an overview of phosphorus recycling technologies and their development, underlining that regulation drives technology development (e.g. Germany and Switzerland P-recycling obligations). In particular, technologies are today available for phosphorus recovery from sewage sludge incineration ash and animal by-product ash, with a number of full-scale plants at the construction or commissioning stage. The successful processes will probably be those which are economic, accept different input materials and produce products adapted to market needs.
The final two RELACS webinars on potential and risks of use of recycled nutrient products in Organic Farming considered contaminants, recycling routes and Life Cycle Analysis (following on from the first three webinars already summarised in ESPP eNews n°53) and concluded with discussion of how use of recycled nutrients is considered in the EU Organic Farming Regulation and perspectives for using recycled nutrients as Organic Farming inputs in the future.
Robin Harder, SLU (Swedish University of Agricultural Sciences), presented possibilities of recycling nutrients from human faeces and urine and from municipal sewage. When excreta are collected separately at the source (to date only marginal in Europe), this can provide nutrients in a more concentrated form and with less contaminants than in municipal sewage, though pharmaceuticals and hormones are still potentially present. Technically, it should be possible to obtain clean and safe recycling fertilisers from both source-separated urine and faeces and from municipal sewage. In case of recovery from municipal sewage, the focus is often on phosphorus, whereas with recovery from source-separated excreta, a broader focus on more nutrient elements is more common.
Kristian Koefoed Brandt, University of Copenhagen, summarised knowledge on antibiotic resistance genes (ARGs) in organic waste streams and in soils. Farmland application of organic fertilizers typically leads to a transient increase in abundance and diversity of antibiotic resistance genes (ARGs). Metals such as copper and zinc may constitute persistent selection pressures for antibiotic resistance (co-selection) in some agricultural soils, whereas antibiotic residues tend to be quickly biodegraded or inactivated in soil (Song et al., 2017). Results from a recent Swedish agricultural field trial indicated that 40 years of sewage sludge application did not have any clear effects on ARGs most likely due to competitive exclusion of sludge-derived bacteria (Rutgersson et al., 2020).
Lukas Egle, Vienna Municipality, presented the City’s objective to recover phosphorus from ash from mono-incineration of sewage sludge, and maybe in the future, also animal by-products. The incineration route ensures elimination of organic contaminants and microplastics, and heavy metals are removed in the ash processing. In Austria, sewage contains around 1 kgP/person per year, and phosphorus in animal by-products is a further 0.5 – 0.6 kgP/person/year. If this were fully recovered, it would represent nearly half of Austria’s mineral phosphate fertiliser use.
Ludwig Hermann, Proman and ESPP President, summarised conclusions of LCA comparisons between mineral fertilisers and recycled nutrient products under the Phorwärts (see ESPP eNews n°28), Systemic and Lex4Bio projects. Greenhouse gas emissions from mineral phosphate fertiliser production are relatively limited, 1 – 1.5 kgCO2-eq./kgP2O5, compared to 9 -11 kgCO2-eq./kgN for mineral nitrogen fertilisers. Environmental impacts of most recycled P-fertilisers are lower than those of mineral P-fertilisers, particularly if heavy metals are removed. However, the lower impact is not guaranteed due to high chemicals consumption for some recovery processes or relevant heavy metal concentrations (Zn, Cu, Pb, Cr) compensating the advantage of lower cadmium concentrations. LCA analysis suggests that the most important environmental impacts are freshwater eutrophication (in the use phase), cadmium toxicity (depending on the source of rock used) and risk of accidental pollution from phosphogypsum waste stocks (generally around historic production sites, see article on Tampa, Florida, below). Difficulties are that various different LCA methodologies are not compatible, results depend very strongly on definition of boundaries and allocation of impacts to different outputs, non-coverage of accidental pollution risks in LCAs and need for probabilistic risk assessment for pollutants.
Bernhard Speiser, FiBL, outlined key points of the EU Organic Farming Regulation relevant to use of secondary nutrient materials. A material can only be used as an input (e.g. fertiliser) in Organic Farming if it is specifically listed in the Regulation annex. At present, a number of secondary nutrient materials are listed (with various specific conditions, in particular “not from factory farming”): manure, dejecta of insects and worms, composted/digested household biowaste, biogas digestate, mushroom culture waste, slaughterhouse wastes, alcohol industry stillage, mollusc waste, egg shells, industrial lime from sugar or salt production. The Regulation also fixes some general principles: input materials must be from plants, algae, animals, microbes or minerals (i.e. not chemically processed) unless such materials are not available in sufficient quantity or quality. Also (art. 5) mineral fertilisers must be “low solubility”.
Frank Oudshoorn, SEGES Denmark and member of EGTOP (the EU expert group on Organic Farming) explained that this group examines proposals to add additional input materials to the Regulation annex, when a dossier is submitted with support of a Member State. EGTOP examines whether the proposed material is needed for Organic Farming, safety, and assesses conformity to the overall principles of Organic Farming: natural or Organic origins of the material, low solubility, principle for fertilisers of feeding the soil not the plant. However, Member States may sometimes interpret differently. For example, Denmark has, in advance, accepted use in Organic Farming of ammonium sulphate recovered from digestate by combining stripped ammonia with stripped sulphur – because it was considered the production process was a “mechanical” concentration of digestate. The process has however not been used yet.
Anne-Kristin Løes, NORSØK (Norwegian Centre for Organic Agriculture), underlined the need for a scientific approach to defining terminology used in the Organic Farming Regulation, such as “natural”, “low solubility”, “physical processing”. This is explored in Løes and Adler, 2019 which discusses the dilemmas between “natural” and sustainability and recycling; between “low solubility” and clean, low contaminant products, between “non-chemical processing” and efficient use of natural resources. The concept of “natural” in Organic Farming is explored in Verhoog 2003 and 2007.
Jakob Magid, University of Copenhagen, summarised a study underway in Denmark on opinions of committed Organic consumers on the use of recycled materials as inputs to Organic production. This suggests that there are two types of committed Organic consumers, at present of similar proportions: those who see Organic products as “pure and clean” and find abhorrent recycling of wastes to Organic farming, and those who favour “sustainability” and consider recycling as an important path towards a more sustainable food system.
In discussions with webinar participants and from the presentations at the five webinars, the following possible conclusions were proposed and will be elaborated in a synthesis document:
RELACS (Improving Inputs for Organic Farming), Horizon 2020 https://relacs-project.eu/
A review of around 100 scientific publications concludes that eutrophication significantly increases greenhouse gas emissions from freshwaters (CO2, methane, N2O). An increase of 5 µg/l of chlorophyll-a in lakes and reservoirs worldwide would result in an increase of GHG emissions equivalent to >6% of fossil fuel CO2.
The current GHG emissions from freshwaters worldwide are estimated to be equivalent to >30% of global fossil fuel CO2 emissions (56% from freshwater CO2 release, 40% from methane, 4% from N2O).
Eutrophic shallow lakes are estimated to emit nearly 50% more methane than comparable non-eutrophic lakes. Eutrophication increases organic matter production in fresh waters, but it is unclear whether the resulting net CO2 uptake will compensate for increased methane production, because the organic matter produced is readily degradable. Increased nitrogen loading to surface waters can cause them to shift from being N2O sinks to net N2O emitters. Eutrophication also increases freshwater GHG emissions indirectly, for example, by shifting from vegetation dominated by macrophytes to algae, whereas macrophyte roots tend to reduce methane production by moving oxygen to sediments. Also, cyanobacteria readily produce methane even in the oxic water zone, both at day and at night.
The review also shows that climate change is expected to significantly increase freshwater GHG emissions and eutrophication (see also ESPP SCOPE Newsletter n°137 on climate change and eutrophication), with positive feedback loops. Increasing temperatures will increase release of nutrients from sediments (accelerated mineralisation), as will extreme climate events (remobilisation of sediments). Both will also lead to increased nutrient losses from land to freshwaters. Increased temperatures may also favour methane production in freshwaters, rather than methane consumption.
This review confirms that policy makers need to further reduce nutrient inputs to surface waters, both because climate change will increase eutrophication risks, and because freshwater eutrophication contributes significantly to greenhouse gas emissions.
“The role of freshwater eutrophication in greenhouse gas emissions: A review”, Y. Li et al., Science of the Total Environment 768 (2021) 144582 https://doi.org/10.1016/j.scitotenv.2020.144582
Pot trials in China using pakchoi (Brassica chinensis) suggest that pyrolysis at 400 – 450°C for 30 minutes reduces ARGs (antibiotic resistance genes) to levels comparable to those in control soil. The tests compared composted pig manure (“high temperature” composting for several weeks) from two different farms to control soil (collected from farmland) and to pyrolysed composted manures (biochar). Compost was added to the pots at 4% dw/dw, and the biochar at 1.2% (equivalent because biochar yield was c. 30% of compost input dw/dw). The pots to which compost was added showed much higher levels of ARGs and of MGEs (mobile genetic elements) on the day of application than the control and biochar pots, between which there was no significant different in number of ARGs. Levels of ARGs were still higher in the compost pots after 40 days. The authors conclude that pyrolysis to produce biochar mitigates ARGs in manure.
In a paper cited, H. Liao et al. compared impacts of two composting systems, large scale (c. 20 tonnes), on levels of ARGs in sewage sludge: hyperthermophilic composting (total time 25 days, of which 15 days > 70°C), conventional composting (total time 45 days, 5 days > 55°C). The hyperthermophilic composting showed significantly better reduction of ARGs and MGEs, and shorter half-lives, compared to conventional composting. Hyperthermophilic composting reduced resistance to different antibiotics by 60 – 85 %, whereas conventional composting reduced resistance by 30 – 40%.
“Turning pig manure into biochar can effectively mitigate antibiotic resistance genes as organic fertilizer”, X. Zhou et al., Science of the Total Environment 649 (2019) 902–908 https://doi.org/10.1016/j.scitotenv.2018.08.368
A paper based on literature and 17 stakeholder interviews concludes that attitudes to agricultural use of sewage sludge in Sweden (after treatment such as composting or anaerobic digestion) are highly polarised. Fear of contamination, in particular “unknown or unfamiliar” risks, and “feelings of disgust” are obstacles to acceptance, despite the benefits of recycling nutrients and organic matter. Stakeholders interviewed were 5 famers or farmers’ cooperatives, one food retailer, one NGO, sewage works operators, regulators and consultants. An identified need is better monitoring and risk assessment of emerging contaminants such as PFAS or microplastics. The study concludes that use of sewage sludge in agriculture brings important benefits but that the priority should be better understanding and control of risks.
“Resources and Risks: Perceptions on the Application of Sewage Sludge on Agricultural Land in Sweden, a Case Study”, N. Ekane et al., Front. Sustain. Food Syst. 5:647780, https://doi.org/10.3389/fsufs.2021.647780
Dairy industry wastewater phosphate removal sludges, resulting from use of aluminium or calcium to precipitate phosphate to sludge, were compared to superphosphate for P-fertiliser effectiveness, on grassland in a field trial in Ireland on P-deficient soil. The P was applied on 12th April and grass was harvested on 24th May, 17th July, 26th September and 6th February of the following year. Differences in grass biomass yield were not significant compared to control, neither for the superphosphate nor for the dairy sludges. Differences in grass P concentration were not significant compared to control for any treatment in the second and third harvest, but were significantly higher with superphosphate in the first harvest, and significantly higher with both of the dairy sludges in the fourth harvest. The authors calculate that the fertiliser replacement value for the first harvest was 50% for the aluminium sludge and only 16% for the calcium sludge, but increasing to around 100% over time (one year, fourth harvest) for the aluminium sludge. They conclude that P fertiliser replacement value of dairy sludges varies significantly depending on the P-removal process and that appropriate information should be supplied to farmer to enable appropriate P management.
“Differing Phosphorus Crop Availability of Aluminium and Calcium Precipitated Dairy Processing Sludge Potential Recycled Alternatives to Mineral Phosphorus Fertiliser”, S. Ashekuzzaman, Fertiliser. Agronomy 2021, 11, 427 https://doi.org/10.3390/agronomy11030427
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ASLO (Association for the Sciences of Limnology and Oceanography) Special Session (SS06) on Methane Accumulation in Oxic Aquatic Environments: Sources, Sinks and Subsequent Fluxes to The Atmosphere. Within the 2021 Aquatic Sciences Meeting (online, 22-27 June 2021). In partnership with the Leibniz Institute of Freshwater Ecology and Inland Fisheries (IGB) and ASLO, ESPP and SPA will follow-up with a webinar to exchange between science, water stakeholders and policy makers on implications of aquatic methane emissions for nutrient management. Proposals for input are welcome.
ASLO special session on methane in oxic aquatic environments: https://www.aslo.org/2021-virtual-meeting/session-list/
Contact Mina Bizic
To contribute to the ESPP- SPA- IGB webinar: contact
The 4th European Sustainable Phosphorus Conference (ESPC4) is postponed (because of Covid). New dates are 20-22 June 2022 in Vienna. PERM, the European Phosphorus Research Meeting will be held virtually 2nd June 2021, see below.
Updates: see www.phosphorusplatform.eu and https://phosphorusplatform.eu/espc4
This meeting, co-organised by ESPP, Biorefine Cluster Europe and ETA Renewable Energies, will link science, industry, agriculture and policy makers. EU-funded projects on nutrient sustainability and phosphorus recycling (Horizon2020, Interreg, LIFE…) and national and company nutrient projects will present, enabling dialogue and synergies. PERM will address how to improve uptake of project recommendations by policy makers and users, through to market, and identify perspectives for research and policy, and implementation gaps.
In parallel to PERM, ESPP is updating our online ‘inventory’ of nutrient-related R&D projects here.
PERM4 – online – 2nd June 2021: event website: www.phosphorusplatform.eu/PERM4
Proposals are welcome for presentations of studies into what factors in nutrient R&D projects improve uptake of conclusions by policy makers, industry and users.
If you wish your project to be included in the programme and/or added to the inventory of projects, please contact
A stakeholder webinar will present and discuss the results of the PeGaSus (ERA-NET) research project (Phosphorus efficiency in the chicken Gallus gallus and pig Sus scrofa) 22nd April 2021, 15h-17h CEST Topics will cover feeding strategies, animal physiology and genetics, soil agro-ecosystems, phosphorus re-use and recycling options, measures of farmers’ economic performance, legislative aspects on manure management, and governance & policy instruments.
Programme and registration: http://pegasus.fbn-dummerstorf.de/stakeholder_workshop.html
This two day virtual conference (270 Euros registration) includes a session on phosphorus, 22nd April, 13h – 14h30 CEST, with EasyMining, LKAB, RISE, Grängesberg apetite mining project, University of Boras, Technical University of Denmark DTU.
https://www.circularmaterialsconference.se/
Presentation of an evaluation by EBA (European Biogas Association) and ECN (European Compost Network) of the interest to place compost or digestate organic fertilisers on the market under the new EU Fertilising Products Regulation and discussion with the European Commission
“Digestate valorisation under the Eu Fertilising Products Regulation”, 28 April 201, 10h-12h CEST online https://attendee.gotowebinar.com/register/1601772252033859597
One day conference 13 May 2021 on resource recovery from wastewaters and biosolids, covering nutrient recovery, hydrogen and other materials: experience from pilot and full scale plants; market pull, user confidence and business models, regulatory framework, links to net zero carbon 2030 agenda for the UK wastewater industry.
“The Art of the Possible: Resource Recovery from Wastewater and Bioresources”, May 13th 2021 online https://conferences.aquaenviro.co.uk/events/conferences/resource-recovery-from-wastewater/
The webinar organised by ESPP with EABA (European Algae Biomass Association, 22nd March 2021, brought together over 400 participants online (from 700 registrants, all of whom have access to meeting networking) including the European Commission (ENV, GROW, MARE, SANTE, RTD, EASME, JRC). Presentations identified and illustrated regulatory questions around valorisation of algae and plants grown using secondary resources in a range of sectors (municipal wastewater, green waste, eutrophication remediation, cement industry (CO2 capture), aquaculture, manure digestate, dairy processing ...) with active discussion in the chat. Questions raised included waste status of algae, contaminants and safety, use in animal feed or fish feed, use in Organic Farming, human food, biofuels … ESPP will now develop a summary of this webinar, including a list of regulatory questions and opportunities, and work on proposals to take these forward (see below a first action on End-of-Waste status for secondary materials from waste waters).
Event webpage: slides, Chat transcript: www.phosphorusplatform.eu/algae2021
Full recording of webinar can be seen on ESPP’s YouTube channel
https://www.youtube.com/channel/UCMid-39AIMT-3pzjoY58qiQ
The European Commission is currently defining a list of secondary material streams for “scoping of development of EU End-of-Waste and By-Product criteria”, as specified in the EU Circular Economy Action Plan (11th March 2020, ESPP eNews n°42). This Action Plan cites “Food, water and nutrients” as one of seven identified Key Product Value Chains. As an action from ESPP’s webinar on regulatory status of waste-grown algae (see above), ESPP is preparing with a number of companies and stakeholders, a joint letter requesting that specific recovered material streams from municipal wastewater (and biomass-derived wastewaters) should be considered for EU End-of-Waste status: algae and biomass grown in waste waters, fibres & polymers etc., nitrogen stripping, phosphate salts for industrial applications. The draft letter is available here and companies and organisations interested to co-sign are invited to contact ESPP.
Contact:
The European Commission has announced that it will prepare in 2021 an Integrated Nutrient Management Action Plan (INMAP), as announced in the Farm-to-Fork Strategy and in the new EU Circular Economy Action Plan. After wide consultation of our members and network of stakeholders, ESPP has prepared and submitted to the European Commission proposals for the objectives, content and implementation tools of such an Action Plan. ESPP’s input presents a proposed ambitious EU strategy on nutrients, across all relevant policy areas, and a comprehensive set of concrete policy actions and tools. ESPP is open for further comments and input on this document, in that the development of the EU INMAP Action Plan is expected in 2021 to include consultations enabling to make further input.
ESPP input to INMAP 27/3/2021 www.phosphorusplatform.eu/regulatory
EU Farm-to-Fork Strategy, COM(2020)381, 20th May 2020 here
EU new Circular Economy Action Plan, COM(2020)98, 11th March 2020 here
Good progress was noted on several dossiers at the EU Fertilisers Expert Group 18-19 March 2021. The meeting also received updates on the European Commission (DG Environment) study underway into contaminants and possible risks of organic-containing and of mineral fertilisers (see detail and call for data in ESPP eNews n°52), ECHA work underway towards restrictions on microplastics under REACH, and on the update of the EU Organic Farming regulation annexe listing fertilising materials authorised for use in Organic Farming. It was noted that the principle of inclusion of sewage-recovered struvite and calcined phosphates in Organic Farming was approved by the EU scientific committee (EGTOP) in 2016. ESPP requested that, as the STRUBIAS criteria are now finalised (subject to formal adoption and publication, see below), the Commission should now engage discussions to define the conditions and legal wording for inclusion of these two materials into the next update of the Organic Farming regulation annexes.
EU Fertilising Products Regulation 2019/1009 https://ec.europa.eu/growth/sectors/chemicals/specific-chemicals_en
EU Fertilisers Expert Group documents (CIRCAB): https://circabc.europa.eu/ui/group/36ec94c7-575b-44dc-a6e9-4ace02907f2f
This meeting technically validated the finalised texts of the “STRUBIAS” criteria to add struvite and phosphate salts, ash / ash derived materials and pyrolysis materials (inc. HTC, biochars) as component materials in the EU Fertilising Products Regulation. Except some minor tidying of legal wording, the criteria remain as published for the public consultation (see ESPP eNews n°51). Hopefully, the finalised criteria will now be published in coming months, in time for the entry into implementation of the new Fertilising Products Regulation itself in June 2022.
STRUBIAS criteria, as published for the public consultation February 2021)
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12136-Pyrolysis-and-gasification-materials-in-EU-fertilising-products
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12162-Thermal-oxidation-materials-and-derivates-in-EU-fertilising-products
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12163-Precipitated-phosphate-salts-and-derivates-in-EU-fertilising-products
Following the Joint Letter coordinated by ESPP and signed by a number of industry federations and companies (mineral fertilisers, organic fertilisers, biostimulants, see ESPP eNews n°51), the European Commission provided answers on several points in a proposed update to the “Frequently Asked Questions” document, which is published and regularly extended and updated on the Commission website, and which provides guidance on interpretation and implementation of the Regulation.
The proposed additional FAQs clarify that:
European Commission “FAQ” for the Fertilising Products Regulation here (current version online = 21/12/2020).
Joint industry letter and European Commission reply here.
The European Commission presented progress of work on criteria for use of by-products as component materials (CMC11) in CE-mark fertilising products.
It is now under consideration to specify not only a short, limitative list of certain by-products, with specific contaminant and other criteria for each one, but also to add a category “CMC-WW” which could cover any by-product coming from a “production process or gas processing / gas emissions control process” which is reach registered, relevant for trade, has agronomic value, offers “high purity” and does not contain specified contaminants (to be defined). Questions raised are: will this concern organic materials or only mineral chemical by-products? Will it concern by-products from waste treatment processes or waste recycling processes?
To date, only four categories of by-product were proposed for inclusion in the short list for CMC11, from: fossil fuel refining (possibly widened to some chemical industry by-products, such as ammonium from caprolactum …), refining of minerals, ores and metals (but phosphogypsum seems to be not included), some gas cleaning systems (but not from waste or manure treatment, see below), processing of biomass, water, food, drink, biorefineries, including from the pulp and paper industries.
“Technical proposals for by-products as component materials for EU Fertilising Products” (2nd report), European Commission JRC, 27th November 2020 here. Comments must be submitted via a member of the EU Fertilising Products Expert Group. ESPP is a member, so you can send comment to and we will forward them.
JRC proposals for CMC-WW see document “2021.03.18 CMC 11 CRITERIA_JRC STUDY PROGRESS.PDF” at the Fertilising Products Expert Group CIRCAB site https://circabc.europa.eu/ui/group/36ec94c7-575b-44dc-a6e9-4ace02907f2f
The meeting also validated in principle a number of technical modifications to the Annexes of the EU Fertilising Products Regulation concerning traces of substances subject to limits for food and feed (limit values, labelling), clarifications concerning fertilising products which also have a plant protection effect, typologies of micronutrient fertilisers, contaminants in certain growing media, acceptance of natural, biodegradable and soluble polymers (e.g. in processing and handling additives), chelating agents, tolerance rules for labelling, fiberised plant materials, category 2 & 3 animal by products (including manures) in composts and digestates.
Draft document “Fertilising products - technical update”
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12135-Technical-amendments-to-the-annexes-to-the-Fertilising-Products-Regulation
The industry associations EBIC -biostimulants) and ECOFI (organic fertilisers) have published a detailed 30-page position paper on Animal By-Products (ABPs) in the EU Fertilising Products Regulation (FPR). The paper underlines that there is a long history of safe use for a range of Animal By-Products (many of which have significant nutrient content), for example in over 62 000 controls in Italy, only nine cases required further investigation for pathogens, and all nine were finally determined to be negative for contamination. EBIC and ECOFI raise six questions about the process for establishing the ABP End-Points necessary for their use in EU fertilising products in the FPR. The paper provides detailed information on the transformation, legal status, FPR relevance, risks and management for 20 different ABPs today used in fertilising products. The document reminds that art. 46(4) of the FPR obliges the European Commission to engage an assessment to establish whether certain ABPs already widely used in Europe in fertilising products can be included in FPR CE-mark fertilisers and questions why some materials in this list are not in the terms of reference of the mandate given to EFSA in May 2020 (2020-0088 here, see ESPP eNews n°50): meat and bone meal, hydrolysed proteins Cat3, processed manure, glycerine etc from biofuels, derived products from blood, hoofs and horns. EBIC and EFSA also question why existing End Points in the Animal By-Product Regulation 142/2011 seem to be opened to question, but not others. The question is also raised as to why the mandate to EFSA does not take into account that the FPR will ensure certain safety levels through the limits to contamination and pathogens fixed in the PFCs.
EBIC & ECOFI joint position “End points for animal by-products used in EU Fertilising Products should recognise the history of safe use of many common materials”, European Biostimulants Industry Council (EBIC) and the European Consortium of the Organic-Based Fertilizer Industry (ECOFI), March 2021 here.
The European Commission has opened a public consultation (to 23 April 2021) on a proposed update to the annex of the EU Organic Farming Regulation 2018/848 which specifies which substances can be used in Organic Farming in Europe, in particular as fertilisers, soil conditioners, pesticides and disinfectants.
Iron(III) phosphate (ferric phosphate) and diammonium phosphate (only in traps) are authorised as pesticides and phosphoric acid for cleaning/disinfection.
Authorised P-containing secondary nutrient sources containing phosphorus include (subject generally to specific conditions or criteria): materials of plant origin, manures (“factory farming origin forbidden”), source-separated household organic waste, biogas digestate, some animal by-products, algae, sawdust and wood ash (“not chemically treated after felling”), soft ground rock phosphate (subject to EU Fertilising Products Regulation contaminant limits), aluminium-calcium phosphate, Thomas phosphate slag, mollusc waste and crustacean chitin (from sustainable fisheries or Organic aquaculture), certain anoxic organic-rich freshwater sediment, biochars from plant materials.
Authorised P-containing animal feeds include a number of phosphate chemicals “of mineral origin” and fishmeal/oils/etc from sustainable fisheries (with specific conditions).
Monocalcium phosphate is authorised in Organic bakery products (raising agent) and diammonium phosphate in Organic alcoholic beverages.
ESPP will input to the public consultation underlining that Organic farms often have negative phosphorus, potassium and sulphur balances, and that increasing use of recycled phosphorus materials is needed to maintain Organic Farming productivity and soil health and to achieve the Farm-to-Fork target of 25% Organic Farming in Europe. ESPP underlines also that Regulation 2018/848 art.5(c) specifies as a “general principle” of Organic Farming “the recycling of wastes and by-products of plant and animal origin as input in plant and livestock production”. ESPP will request that the positive EGTOP Opinion of 2/2/2016 on acceptance of struvite and calcined phosphates from municipal wastewater should be implemented, and that other recycled phosphate materials should be assessed for acceptance into Organic Farming.
Public consultation to 23 April 2021: “Organic farming - list of products & substances authorised in organic production (update)” here.
The European Commission has published an “Action Plan for the Development of Organic Production”, aiming to increase Organic production in the context of the Green Deal target of 25% of EU agricultural land by 2030 (compared to 8.5% in 2019, and an estimate of 15-18% by 2030 if no action is taken beyond current policies). Member States are asked to fix national targets to achieve together this EU total. The Action Plan has three axes (23 actions): promote Organic food and products ensure consumer trust (including public purchasing), conversion from conventional to Organic agriculture and improving the contribution of Organic Farming to sustainability, and an emphasis on supportive R&D. Action 16 includes developing animal feeds based on algae, aquaculture wastes and insects. Action 23 aims at more efficient use of resources and (alongside biodegradable and compostable plastics) will “promote … the reduction of nutrient release”. The Action Plan however fails to mention recycling (except one mention of plastics) and does not address how increased Organic production can be achieved without new sources of nutrient input, in particular – for sustainability objectives – recycled nutrients.
European Commission Communication “on an Action Plan for the Development of Organic Production”, 25th March 2021, COM(2021)141 - SWD(2021)65 here and annex
FiBL and RELACS are organising five 2-hour webinars to exchange between researchers and Organic farming stakeholders to gather knowledge on potential risks of use of recycled fertilisers.
To date, this webinar series has some 140 registrants (including nearly 20 speakers), with around 70 researchers and over 30 Organic Farming organisations and a range of other stakeholders.
Remaining webinars:
- How to recycle nutrients from human excreta, 12 April 2021, 14h – 16h Paris summer time (CEST)
- Socioeconomic aspects and final discussion , 22 April 2021, 10h – 12h Paris summer time (CEST)
To register, contact:
The first webinar (3 March 2021) set the scene. A survey of over 70 Organic farms by RELACS shows concern about contaminants, especially in composts and digestates, particularly from household wastes.
Marie Reimer, Hohenheim University summarised data on European Organic farm nutrient balances. The balance is often positive for nitrogen but negative for phosphorus and potassium, especially in specialist arable Organic farms (without livestock). Farms which rely largely on BNF (biological nitrogen fixation) have more negative P and K balances (see further information in ESPP eNews n°49).
Jakob Magid, Copenhagen University, presented field trials in Denmark (CRUCIAL study) over nearly twenty years, applying sewage sludge to levels equivalent to two centuries normal application. So far no unwanted effects (except nutrient loss) have been found on soil and crops caused by recycling of societal wastes in accelerated amounts. Heavy metals in sewage sludge have fallen considerably over recent years. Copper and zinc need to be reduced in animal feeds, to reduce levels in manure. Also, a risk assessment concluded that the risk associated with agricultural use of Danish sewage sludge is comparable to that of animal slurry, once the EU limits for Zn and Cu addition to pig feed have been fully implemented, which should be the case from 2022.
Erik Smolders, KU Leuven, explained that copper and zinc, mainly from manures, and cadmium, mainly from mineral phosphate fertilisers, are the main concerns in agriculture. However, plant availability of metals is more important than loads, and this depends on soil type.
Discussion concluded that Organic farming needs to increase nutrient use efficiency in order to improve productivity and sustainability, and to increase nutrient inputs in some Organic systems such as arable and vegetables. Organic farmers in Denmark tend to consider that it would be preferable to use recycled nutrients from societal wastes, including in the longer term from municipal sewage, over using conventional manure. Questions were raised on whether easily soluble recycled fertilisers could be acceptable.
The second webinar (11 March 2021) discussed the scientific data on the risks of organic chemicals, microplastics and pathogens in manure and sewage sludge.
Stephen Smith, Imperial College London, explained that contaminants in sewage sludge have been considerably reduced over the last few decades. Most toxic chemicals are adsorbed in soil, so have low biological activity, and negligible crop uptake, so that use on cropland seems to not be a concern. Transfer to diet via livestock does however require attention but studies spiking cattle feed with sewage sludge showed very low and temporary, or non-detectable, transfer to milk (see ESPP Scope Newsletter n°126). There are over 23 000 chemicals registered under REACH in the EU, of over 100 000 on the chemicals inventory. Many enter secondary resource streams and can pose risks in recycling. Problematic chemicals today are brominated dioxins (resulting from brominated flame retardants), chlorinated alkanes (restricted under POP regulations, but still present in secondary resources) and PFAS/PFOS (perfluorinated chemicals, for which EU further restrictions are now being discussed). QSAR (modelling) analysis of new brominated flame retardants introduced to replace banned substances suggests that these will also prove problematic in the future. Overall, halogenated chemicals are problematic, and the solution is to stop producing and using these. Another problem is the illegal presence of restricted substances in imported articles.
Moritz Bigalke, University of Bern, presented current understanding on microplastics. Significant levels can be present in sewage sludge or composts. The main inputs to soils seem to generally be vehicle tire dust, sewage sludge, compost and agricultural films. While most studies show ecotoxicological impact only at high concentrations of microplastics, one study (Rodriguez-Seijo et al. 2017) suggest that microplastics may impact earthworms at environmentally relevant levels. Microplastics are mobile in soils, can modify soil properties and impact plants (see ESPP eNews n°38). A major difficulty is the absence of standard methods for analysing microplastics in soils and their impacts on soil organisms.
Annika Nordin, SLU (Swedish Agricultural University), presented pathogens in sewage sludge and manures. Treatments such as composting, anaerobic digestion or ammonia sanitisation reduce pathogens to low and safe levels, while storage or alkaline treatment are not efficient against helminth eggs (which are a big problem e.g. in Africa). The EU Sewage Sludge Directive today still allows spreading of untreated sewage sludge if ploughed in within 24 hours.
Discussion concluded that more research is needed into microplastics and into the fate and risk assessment of organic chemical contaminants in soil-plant systems. Input should perhaps be made to the European Commission to propose that the current revision of the Sewage Sludge Directive should ban the spreading of untreated sewage sludge.
The third RELACS webinar (17 March 2021) saw several presentations on recycled nutrient materials.
Kurt Möller, Hohenheim University, presented studies on composts and digestates, showing considerably preferable LCA for anaerobic digestion compared to composting, and also much lower nitrogen losses during processing, but a higher N loss risk for digestates after field application. The long-term fertiliser efficiency of P and K in organic fertilizers is nearly 100 %, but the long term N efficiency varies in a wide range, for compost it is only 20-40%, whereas it can be nearly 70 to 80% for digestates. Both, N losses during storage and after field applications, and low efficiencies in the field affect the stoichiometry of nutrients in organic manures, mainly the N/P- and the N/K-ratio. Therefore, the use of composts (e.g. from food waste) to provide N to crops can result in nutrient imbalances in the soil, leading over time to e.g. phosphorus accumulation. Any treatment approach should emphasize on reduction of any kind of nutrient losses.
Elke Bloem, Julius Kühn Institute and PROMISE (Baltic Bonus project), summarised a study looking at mesophilic anaerobic digesters treating over 40 different input materials including sewage sludge, pig, cattle and poultry manure and maize (as a reference). Eight antibiotics were measured in input materials and in digestate (sulfonamids, tetracyclines, fluoroquinolones). At least one antibiotic was detected in 70-90% of input manures and 100% of sewage samples, with similar detection levels in digestate. Anaerobic digestion reduced median antibiotic levels by around 50%, but high levels were still present e.g. in poultry manure digestates. For comparison, literature data suggests reduction levels of 30% - 100% in composting, very variable even for the same substance in different composting systems (depending on time, temperature, pH, aeration …). The PROMISE study also carried out ecotox tests using Sinapsis alba (white mustard), showing effect concentrations of the order of 1 000 x higher than worst case calculated soil concentrations. However, the tests also showed that effects of several antibiotics are more than cumulative (synergistic) and should be considered. Also, some literature studies suggest that antibiotics may stimulate antibiotic resistant genes (AGRs) at significantly lower concentrations.
Anne-Kristin Løes, NORSØK, summarised studies on use of hydrolysed fish processing and seaweed processing wastes as fertilisers. Ground fish waste treated in formic acid (pH4) showed to be a very effective nitrogen and phosphorus fertiliser (hydrolysed proteins) in a field trial with rye grass, producing as much biomass as the reference treatment with the same N dose supplied as poultry manure, but with a much more rapid growth response. In the trial, this material was also tested with fibre residue from processing of rockweed (seaweed), from the company ALGEA (Syngenta), rich in K, S, Mg. Both of these residues are currently generally incinerated. Fish processing residues from caught wild fish are currently authorised for use in Organic Farming, whereas this is not clear for fish residues from aquaculture (category 2 waste not accepted; fish excrements not accepted). For further information, see Ahuja et al. review on fish waste based fertilisers.
Erik Meers, Gent University, presented a number of projects working on different routes for processing digestates to generate fertiliser materials, as a solution to transfer excess nutrients from intensive livestock regions to regions needing nutrients for arable production.
Participants discussed manures from digestate, questioning that such processing may only necessary or economic (as opposed to local use of the digestate) in intensive and concentrated livestock production, which is against the principles of Organic Farming.
The Horizon2020 R&D project, Fertimanure (ESPP member, see ESPP eNews n°41 Innovative nutrient recovery from secondary sources: production of high-added value FERTilisers from animal MANURE) has opened a survey of fertiliser users (in Europe, Argentina, Chile). Forty-seven questions ask about farm type and size, soil sampling, farm fertiliser management plan, fertiliser application costs, readiness to switch to Organic Farming or to bio-based fertilisers, familiarity with regulations, qualities considered important for bio-based fertilisers, materials considered acceptable in bio-based fertilisers, etc.
Fertiliser user questionnaire: https://www.fertimanure.eu/en/news/consult/26
An overview of global phosphorus flows in fish production (capture and aquaculture) shows that the net P flow has changed from positive + c. 0.5 MtP/y (more P in harvested fish, both captured and cultured) in the 1960’s – 1970’s to negative – c. 1 MtP/y (more P used in aquaculture than harvested). P in harvested fish is an order of magnitude larger than other P pathways from water to land (migratory fish, seabirds, deposition). P input to aquatic systems from aquaculture globally is estimated at c. 2 MtP/y (2016), rising rapidly since the 1990’s with the expansion of aquaculture. This compares to estimates of losses from croplands and manure of 4 - 5 MtP/y (not including losses related to land use change) and of total river P discharge to oceans of 4 – 22 MtP/y. ESPP note: these numbers are coherent with global phosphate rock mining of 17 – 24 MtP/y (ESPP Factsheet). The authors estimate that c. 0.3 MtP/y of mineral phosphate is used in aquaculture feed. The authors estimate that global average Phosphorus Use Efficiency (PUE) in aquaculture is c. 20%, higher for finfish than for crustaceans. China represents nearly 60% of global aquaculture P input. In China, upper values for PUE are 44% for finfish and 24% for crustaceans. PRE (Phosphorus Retention Efficiency), that is % of input P retained in fish biomass in feeding experiments, can be higher, e.g. 44% median PRE for carp, which represents c. 40% of world aquaculture production. The authors estimate that an increase of global aquaculture PUE to 48% would be necessary to achieve “net zero” flows in fish capture and production, which would be very demanding. The authors note that aquaculture shows net P use (input – harvest) / protein of c. 0.3 g/g compared to 0.03 – 0.14 g/g calculated for crop-livestock systems.
Huang et al. 2021 “The shift of phosphorus transfers in global fisheries and aquaculture” https://doi.org/10.1038/s41467-019-14242-7
Net influx and efflux of CO2 was calculated for 15 eutrophic, shallow lakes (< 7m) in Iowa, USA (mostly manmade lakes), for which long term water chemistry survey data was available 2000 to 2010. Additionally, dissolved inorganic carbon (DIC) was isotope tested, and dissolved organic matter (DOM was analysed. Without eutrophication, lakes are generally net sources of CO2 to the atmosphere (efflux). In this study of eutrophic lakes, five lakes showed net CO2 influx (sink) of c. -50 to -1800 mmolCO2/m2/day (average during the ice free season = c. 8 months), whereas ten showed net efflux (emission) of c. 320 – 11 800 mmolCO2/m2/day, showing values significantly higher than previously reported in literature. For the lake with the highest net efflux (Badger Lake, 0.17 km2) this represents around 21 000 tCO2/year (based on 8 months). The carbon analysis showed that in all fifteen lakes, the DIC was derived from degradation of lake carbon (e.g. from sediment), mineral dissolution and atmospheric uptake, and not from degradation of land runoff organic carbon. CO2 efflux from the lakes was correlated to total nitrogen and to watershed wetlands. Conclusions are that although algal blooms resulting from eutrophication can cause lakes to uptake CO2 from the atmosphere for periods of months, eutrophication can cause wide changes in CO2 influx or efflux, including in some cases high CO2 emissions. The large effluxes are hypothesised to possibly be related to photodegradation of nitrate and nitrite, related to high nitrogen inputs to the lakes.
Morales-Williams et al. 2021 “Eutrophication Drives Extreme Seasonal CO2 Flux in Lake Ecosystems” Ecosystems (2021) 24: 434–450
https://doi.org/10.1007/s10021-020-00527-2
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Freshwater emissions of methane are of the same order as methane released by wetlands, and a significant contributor to climate change. Nutrient losses to surface waters and eutrophication will impact methane emissions. ESPP and the US Sustainable Phosphorus Alliance summarised recent knowledge in SCOPE Newsletter n° 135 (July 2020).
ASLO (Association for the Sciences of Limnology and Oceanography) is organising, as part of the 2021 Aquatic Sciences Meeting (online, 22-27 June 2021), a Special Session (SS06) on Methane Accumulation in Oxic Aquatic Environments: Sources, Sinks and Subsequent Fluxes to The Atmosphere.
Deadline for abstract submission is 12th March (05:59 GMT, 1600 characters)
In partnership with the Leibniz Institute of Freshwater Ecology and Inland Fisheries (IGB) and ASLO, ESPP and SPA will follow-up the ASLO session with a webinar to exchange between science, water stakeholders and policy makers on implications of aquatic methane emissions for nutrient management. Both the ASLO session and this webinar will be summarised, with an update on recent science, in a further SCOPE Newsletter special edition.
ASLO special session on methane in oxic aquatic environments: https://www.aslo.org/2021-virtual-meeting/session-list/
Contact Mina Bizic
Abstract submission deadline 12 March 2021 (05:59 GMT)
To contribute to the ESPP- SPA- IGB webinar: contact
ESPP is organising a webinar workshop, with participation of the European Commission (DGs ENVI, GROW MARE, JRC) on Monday 22nd March, 9h-13h (Paris time, CET). The webinar aims to identify regulatory questions impacting valorisation of algae grown in wastewaters, or “fed” with other waste streams (e.g. CO2 capture), or for materials left after extracting materials such as biofuels or cosmetics from algae. Algae can be valorised to fertilisers (recycling nutrients and organic carbon to soil), animal feed, bioenergy or to many other applications. Use of nutrients from algae grown using waste inputs raise specific questions under EU fertilisers and animal feed regulations, as well as contaminant and safety questions.
Registration (free): https://algae2021.eventbrite.co.uk
Event webpage, updated programme www.phosphorusplatform.eu/algae2021
A stakeholder webinar will present and discuss the results of the PeGaSus (ERA-NET) research project (Phosphorus efficiency in the chicken Gallus gallus and pig Sus scrofa) 22nd April 2021, 15h-17h CEST Topics will cover feeding strategies, animal physiology and genetics, soil agro-ecosystems, phosphorus re-use and recycling options, measures of farmers’ economic performance, legislative aspects on manure management, and governance & policy instruments.
Programme and registration: http://pegasus.fbn-dummerstorf.de/stakeholder_workshop.html
Members of ESPP benefit from a 10% reduction for registration to “Phosphates 2021”, online 23-25 March 2021. This is the only major global event for the phosphate mining, processing, phosphorus chemicals and phosphate fertiliser industries, and brings together over 400 industry participants every year. This year’s Phosphates conference is online, with virtual exhibition and networking centre, interactive discussion groups, conference presentations with Q&A. Registration prices are considerably lower than usual.
https://events.crugroup.com/phosphates/register
One day conference on resource recovery from wastewaters and biosolids: nutrient recovery, hydrogen and other materials: experience from pilot and full scale plants; market pull, user confidence and business models, regulatory framework, links to net zero carbon 2030 agenda for the UK wastewater industry. Abstract submission deadline: Friday 12th March (200 words).
“The Art of the Possible: Resource Recovery from Wastewater and Bioresources”, May 13th 2020 online.
Abstract submission deadline 12th March https://conferences.aquaenviro.co.uk/events/conferences/resource-recovery-from-wastewater/
The European Commission (DG Environment) has contracted to Arcadis and Arcadia International a study into contaminants in fertilisers (organic and inorganic fertilisers, sold as fertilisers under EU or under national regulations). The declared objective is to identify contaminants, fertiliser additives or fertiliser components or their decomposition products, which pose possible risks for the environment, for crops, for consumers (via crops) or for farmers. ESPP participated in a stakeholder workshop online organised by Arcadis 4th March 2021 (ESPP circulated the invitation to members), with nearly one hundred participants from different concerned companies and sectors. DG ENVI suggested that the study underway could lead to modifications of the EU Fertilising Products Regulation and to “Restrictions” under REACH. A shortlist of substances (mainly contaminants) to be studied has been defined: pyrazoles, dioxins, PCBs, PFAS (perfluorinated alkyls), pharmaceuticals (e.g. diclofenac), cadmium, chromium, mercury, vanadium and fluoride. A preliminary risk scoping will be carried out on these substances by mid-2021, including defining fertilisers concerned, risks, possible risk management measures (e.g. restrictions / limit levels in fertilisers). If potential risks are identified, these will be submitted to ECHA (European Chemical Agency) for additional data collection, risk assessment and then public consultation before possible “Restrictions” under REACH. Companies and stakeholders having data, studies on any of the above listed contaminants in fertilisers are invited to transmit these to Arcadia before end March 2020 (data on levels of these contaminants in fertilisers or in recycled nutrient materials, risk assessments for these contaminants in fertilisers or in soil).
Arcadia study contact
Based in North-East of Germany, HTCycle AG uses biogenic waste as raw material to produce high quality end products, which are like active carbon and can be used for the 4th cleaning step in wastewater treatment plants, as well as ammonium sulphates and struvite for the agricultural sector.
HTCycle AG was established in 2009 and is part of the IPI group (International Power Invest AG), specialised in renewable energy solutions and environmental technologies. The patented HTCycle process is based on hydrothermal carbonisation technology and uses steam as the reaction medium at around 220°C, 24 bars for 3-5 hours. Focusing on sewage sludge with 25-30% dry matter content as raw material, the activated carbon produced from the sewage sludge can be used in the water cleaning process to remove micro plastic, hormones and pharmaceutical residues. Phosphorus can be leached from the HTCycle coal using sulphuric acid, to produce phosphoric acid. Ammonia stripped from offgases can be either reacted with the phosphorus to produce struvite and/or used to produce ammonium sulphate. The process thus complies with the German phosphorus recovery obligation (Sewage Sludge Ordinance of 2017). To date HTCycle AG has more than 10 years of experience operating pilot plants with 8.000 and 16.000 tons of capacity per year and is currently planning to build several full-scale 24/7 operating industrial-plants in Germany together with a European Infrastructure Fund. The first plant will be built in Wolgast, North East Germany, with a capacity of 16.000 tons per year of sewage sludge wet weight. HTCycle AG joins the ESPP because it aims to bring the economic and environmental benefits of hydrothermal carbonization, combined with efficient phosphorus recycling, to the attention of the general and professional public.
https://htcycle.ag/
EasyMining (Ragn-Sells group), an ESPP member, the Swedish University of Agricultural Services (SLU) and Lantmännen Research Foundation (Swedish agricultural cooperative of 20 000 farmers) have launched a project to test calcium phosphate recovered from sewage sludge incineration ash as a phosphorus source in animal feed for poultry and pigs.
The PCP (precipitated calcium phosphate) is produced by the EasyMining Ash2Phos process from sewage sludge incineration ash (see ESPP P-recovery technology catalogue), 600 kg/day pilot operational in Helsingborg, two full scale plants in permitting. It offers high P content, the same P solubility as commercial MCP (mono calcium phosphate) today used in animal feed (90% in citric acid) and low fluorine. The planned trials, to run for two years, will assess the digestibility of the PCP, in order to enable optimal use in animal feed and to minimise losses to manure.
EasyMining underline the need to clarify EU regulation concerning use of products recovered from sewage sludge in animal feeds. ESPP has engaged discussions with the European Commission on this question.
“New project to test recovered phosphorus as feed phosphate” 15/2/2021 https://www.easymining.se/newsroom/articles-news/feed-project/
Royal DSM has launched “Reducing emissions from livestock”, a sustainability platform addressing climate emissions and nutrient stewardship. DSM is a global science-based company in nutrition, health and sustainable living. DSM solutions for livestock include feed additives which improve nitrogen use efficiency (NUE) in poultry and in pigs, and so reducing N losses, improve phosphorus and amino acid digestibility, reduce methane emissions in ruminants and increase overall animal feed use efficiency. Ivo Lansbergen, President, DSM Animal Nutrition & Health: “Amidst global climate change, the need to reduce carbon emissions from animal livestock is increasingly important. It is not a question of whether we need to shift to a more sustainable business model, it is more a question of how fast and with what impact. We need to shift to a model where farmers are getting a fair price for the animal proteins produced, where people across the world have access to affordable proteins, and last but not least, where animal farming reduces its impact on the environment (emissions, water quality through manure measurement, bio-diversity) significantly”.
“Royal DSM N : DSM launches its sustainability platform ‘Reducing emissions from livestock' as part of We Make It Possible”, 21 January 2021 http://www.publicnow.com/view/572B40F4251CEEE2628E2D2033D1295A89DF2425
The Fertiliser Consultants Network (FCN) www.fertcon.net is the first European network of regulatory consultancies for the fertiliser sector. The network can provide expertise across Europe as well as North Africa, South America, Russia and China. Members can provide consultancy on both national and European regulation including implementation of the new EU Fertilising Products Regulation 2019/1009 and of the new Regulation on Mutual Recognition 2019/515, biostimulants, fertiliser additives, organic and mineral fertilisers, Organic Farming. Founding members are Artemisa, Openagri, SILC Fertilizzanti, SUN Chemicals Services, Vox Gaia.
Fertiliser Consultants Network (FCN) www.fertcon.net
The SuMaNu platform (Sustainable Nutrient and Manure Management for reduction of nutrient loss in the Baltic Sea Region) has published a report (by RISE) bringing together recommendations for manure management from seven Baltic manure projects (list below). These projects addressed different aspects of manure management, and this report aims to develop recommendations covering all aspects o sustainable manure use (nutrient utilisation, ammonia emissions, greenhouse gas emissions, nutrient runoff and leaching, manure nutrient recycling, odours, pathogens and contaminants) over the whole livestock production chain (feed, animal housing, manure storage, manure application and manure processing). Costs of manure management, economic and regulatory instruments are discussed. The report concludes that baseline obligatory standards for manure handling and use should be tightened, information of farmers should be increased and economic incentives implemented to help finance sustainable technologies and practices.
Project recommendations summarised in this report: Manure Standards, Baltic Slurry Acidification, GreenAgri, BONUS PROMISE, Baltic Manure, Baltic Deal, and Baltic Compass. “Technologies and management practices for sustainable manure use in the Baltic Sea Region”, E. Sindhöj et al., RISE Report 2020:77, SuMaNu http://ri.diva-portal.org/smash/get/diva2:1476430/FULLTEXT01.pdf
A second report from SuMaNu summarises different manure processing technologies and the resulting recycled nutrient fertiliser products. Regional manure nutrient misbalances in Finland, Sweden, Germany and Poland are assessed. Technologies summarised are: mechanical separation, slurry acidification, compositing, anaerobic digestion, thermal drying, pelletising, pyrolysis, HTC, combustion, gasification, ammonia stripping, membrane separation, struvite precipitation and vacuum evaporation. Fate of contaminants and pathogens are discussed. The report concludes that concentration of livestock production in certain regions generates nutrient surpluses: processing and recycling can enable transport of nutrients to crop-growing regions where they are needed, but manure processing is economically challenging. Incentives are needed to support the high investment costs for processing and to develop markets for recycled nutrient products. These often differ from conventional mineral fertilisers and services to facilitate transfer to their use should be supported.
“Manure processing as a pathway to enhanced nutrient recycling”, S. Luostarinen et al., 2020, SuMaNu https://jukuri.luke.fi/bitstream/handle/10024/546254/luke_luobio_62_2020.pdf
A third report from SuMaNu analyses pitfalls between envisaged and realised impacts of manure nutrient projects, that is whether project recommendations were taken up by policy makers or implemented by farmers. The projects analysed are the Baltic manure projects listed in (1) above. The only project recommendation to achieve high policy maker and farmer uptake was the Baltic COMPASS recommendation to develop manure phosphorus management information, such as P-norms and standard P-indices for manures. Slurry acidification achieved medium policy integration and manure-based biogas production achieved medium policy integration and user uptake. Conclusions are that projects should explicitly define recommendations and make efforts to make these clear and accessible, and that project activities should correspond to objectives. Recommendations are more likely to be implemented if they are well communicated, in line with farmers’ needs, and if representatives of policy makers and farmers are involved in the project.
“Typical pitfalls leading to gaps between envisaged and realised impacts of manure and nutrient related projects - a gap analysis”, H. Lyngsø Foged et al., Organe Institute, June 2020, SuMaNu https://www.organe.dk/docs/SuMaNu_Report_2-3_Gap_analysis_Organe_Report.pdf
SuMaNu has also published six draft policy recommendation sheets, each 2-3 pages. These cover
- Fertilisation planning: in particular recommending obligatory farm gate nutrient balancing for N and P (comparison on nutrient inputs to offtakes, enabling calculation of nutrient efficiency)
- Fertilisation planning measures: development of Baltic region P fertiliser norms, a soil P-index model and tools for manure fertilisation planning, based on manure standards
- Handling and storage of manure: definition of BAT (Best Available Technologies) to reduce ammonia and greenhouse gas emissions, minimum manure storage capacities, spreading in Spring and Summer, application rates based on manure standards
- Regional nutrient reallocation: strategy and measures to support production and use of recycled nutrients from manure, with biofuel production / renewable transport
- Safe manure recycling: reduction of trace elements and pharmaceuticals in feed (then found in manure), improving hygiene of manure processing (avoid recontamination), avoid mixing manure and sewage sludge in processing
- Knowledge transfer between research, regulators and farmers, including via agricultural and environmental advisory services
SuMaNu draft policy recommendations: https://balticsumanu.eu/national-stakeholders-have-their-say-regarding-sumanu-policy-recommendations/
A report from the Ellen Macarthur Foundation (EMF) and Institute for European Environmental Policy (IEEP) concludes that moving to circularity for steel, aluminium, plastics, cement and food could reduce by nearly half these sectors’ climate emissions, so reducing total world greenhouse gas emissions (GHG) by around 20%. Agriculture and food are estimated to contribute 17% of EU GHG. Over 20% of food is wasted in the EU. Combined with methane emissions from waste, global food waste is estimated to contribute 8% of anthropogenic GHG. EMF suggest that circularity in the agri-food system, including “regenerative agriculture” (~36%), reducing food waste (~12%) and recycling food waste back to soil (~2%) could reduce agri-food system GHG by nearly 50%, but most of this suggested reduction depends on “regenerative agriculture” (defined as “crop and livestock production approaches that enhance the health of the surrounding natural ecosystem”).
EMF states that policies needed include a reform of the CAP (EU Common Agricultural Policy), active policies to reduce food waste, separate collection of biowaste (as required by the Waste Framework Directive by 2024) and creating markets for composts and digestates. EMF also notes the need for fiscal reforms to support circularity, including for nutrients.
“A low-carbon and circular industry for Europe”, Ellen Macarthur Foundation and Institute for European Environmental Policy, 2021 https://think2030.eu/publications/a-low-carbon-and-circular-industry-for-europe/
“Completing the picture. How the circular economy tackles climate change”, Ellen Macarthur Foundation, 2019 https://www.ellenmacarthurfoundation.org/our-work/activities/climate-change
In a 20-minute webinar online here, in the US Sustainable Phosphorus Alliance “Science Now” series, Adam Heathcote presents recent work estimating annual carbon capture in freshwater lakes (see paper by Anderson et al. summarised p.16 of SCOPE Newsletter n° 137). Based on a newly collated data set, covering 500 lakes and reservoirs worldwide, in different biomes, they conclude that lakes are a significant global carbon sink, with increasing nutrient losses increasing carbon sequestration to sediments. However, lakes remain a net carbon emitter, with net carbon releases into the atmosphere around twice burial rates. The largest cause of carbon burial is soil erosion, which takes organic carbon to sediments. Also, increasing carbon sequestration in lakes is maybe 15 to 25 times lower (greenhouse equivalent) than possible expected increases in aquatic methane emissions related to eutrophication (see SCOPE Newsletter n°135).
US Sustainable Phosphorus Alliance YouTube channel https://www.youtube.com/channel/UCNFDQTfeT7mGsMY_YOgMonA and Science Now “Nutrients Increase Global Freshwater Carbon Sink” https://www.youtube.com/watch?v=L_IlFjiIfqE
Tests with sewage sludge show that pyrolysis at 400°C (2 hours) remove pharmaceuticals to below detection limits. Pyrolysis at 700°C (2 hours) also eliminated 99% of PVBs, PAHs and EDC/Hs*. The sewage sludge was from a 500 000 p.e. municipal sewage works in the Czech Republic operating chemical P-removal, after mesophilic anaerobic digestion, centrifuge dewatering and then dried in a paddle dryer (100°C, 3 hours). Pyrolysis was carried out in the laboratory on 100g samples of dried sludge, particle size 0.5 - 2 mm, in a quartz fixed-bed reactor, and was tested at 400°C, 500°C, 600°C, 700°C and 800°C in oxygen-free conditions (under helium). The sludge H/C-org ratio was 1.75 and this was reduced to H/C-org <0.7 in >= 500°C biochars, that is conform to the EU Fertilising Products Regulation (draft) STRUBIAS criteria.
Removal of PCBs may not be relevant in that total PCBs in the sewage sludge were < 300 ng/g: levels were reduced to < 30 ng/g in the biochars. Pyrolysis at >= 500°C reduced levels of PAH from 36 µg/g in the dried sludge to around 1 µg/g, that is significantly lower than the 6 µg/g limit proposed in the EU Fertilising Products Regulation (draft) STRUBIAS criteria. Only three EDC/Hs were found in the sludge: bisphenol A, oestradiol, triclosan. Of these, only bisphenol was detectable in any of the biochars, and was reduced from > 1 000 ng/g in the dried sludge to c. 10 ng/g event with >= 500°C pyrolysis. Nine of the twenty-seven pharmaceuticals tested were found in the dried sewage sludge (concentrations 0.1 - 50 ng/g) and all were non-detectable in all of the biochars.
The authors suggest that pyrolysis at >= 400°C for 2 hours is sufficient to ensure complete elimination of the studied pharmaceuticals from sewage sludge biochars. Based on fact that 700°C (2 hours) was sufficient to remove 99.8% of the other organic contaminants tested, the authors suggest the sewage sludge pyrolysis at temperatures higher than 600°C with sufficient residence time (> 30 min) should ensure efficient organic pollution removal. However, this is based on the limited number of different pharmaceuticals found in this sludge and on a limited number of other organic molecules. Also, the study did not assess whether the pyrolysis may have decomposed the pharmaceuticals or other organic contaminants into breakdown products, nor whether microplastics were eliminated. Therefore, further investigations into these questions are recommended.
* PCB = polychlorinated biphenyl. PAH = polyaromatic hydrocarbon. EDC/H = endocrine disrupting chemical or hormone.
“Effect of pyrolysis temperature on removal of organic pollutants present in anaerobically stabilized sewage sludge”, J. Mosko et al., Chemosphere 265 (2021) 129082 https://doi.org/10.1016/j.chemosphere.2020.129082
The RAE (Relative Agronomic Efficiency) for phosphorus of nineteen organic secondary nutrient materials was tested in three independent pot trials (each pot with four replicates, total of 152 pots over three years) with barley, for approx. 12 weeks (to maturity and grain harvest) and compared to single superphosphate fertiliser (SSP). Soil used was sandy, low P (13 mg/kg OlsenP), with pH 5.5 or limed to 5.8 or 6.5. Other nutrients (N, K, Mg, Ca, Fe, Zn, Mn, Cu, B, Mo, S) were applied sufficiently. The organic materials tested were manures/slurries from cattle, pig and fur fox, pig slurry mixed with food industry wastes (raw, composted or digested), sewage sludges (from 3 sewage works using iron salts for P-removal to different extents), pyrolysed and HTC sewage sludges.
The RAE (Relative Agronomic Efficiency) was calculated as the amount of P in SSP needed to produce the same yield as for the organic residue, divided by the total P applied in the organic residue.
At low P application rates, pig slurry, cattle slurry and composted cattle manure showed RAE above 100% (up to 189%). These materials were tested at application rates of 40 mgP/kg soil, whereas the sewage sludge derived products were tested at 150 mgP/kg soil, this being the highest P application rate at which SSP was tested. The manures, applied at only 40 mgP/kg, gave barley yields of yields of 47 – 61 g barley grains per pot, compared to the yield of 76 g grain/pot for SSP at 150 mgP/kg soil (3-13 g/pot only for control with no P addition).
On the other hand, digestate of pig slurry + food and enzyme industry wastes tested at a P application rate of 150 mgP/kg soil showed a calculated RAE of only 35% (yield 49 g/pot).
The authors suggest that the RAEs higher than 100% for manures may be because organic molecules may block P adsorption sites in soil so that P remains better available for crops and indicate that this hypothesis is supported by unpublished results of soil incubation experiments testing pig and cattle manures.
All the sewage sludges and sludge pyrolysis/HTC materials showed low RAEs (when tested at 150 gP/kg). Calculated RAEs were 6 – 68% for the sewage sludges, with yields of 17 – 66 g/pot. Calculated RAEs were 1 – 6% for the sludge or manure pyrolysis/HTC materials, with yields of 5 – 17 g/pot at 150 gP/kg.
The authors identify that the combined iron and aluminium content of the organic materials, i.e. molar ratio (Fe+Al):P, is a very good predictor of RAE for organic residues, correlating negatively to barley grain yield in these pot trials. Calcium was not a good predictor, as were also not phosphorus solubility/extraction methods (formic acid, citric acid, NAC, water, NaHCO3).
“Predicting relative agronomic efficiency of phosphorus-rich organic residues”, K. Ylivainio et al., Science of the Total Environment 773 (2021) 145618, https://doi.org/10.1016/j.scitotenv.2021.145618
After a period of dormancy due to organisation changes, ESPP is relaunching our social media channels: LinkedIn and Twitter. ESPP is now working for communications with ETA – Florence Renewable Energies, a company with over 25 years’ experience promoting green innovation, especially for events, platforms and industry associations in the bioenergy sector.
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Given the ongoing international corona virus situation, it is decided to postpone ESPC4 and PERM (4th European Sustainable Phosphorus Conference and European Phosphorus Research Meeting) to 2022, Vienna, as a physical conference (previous planned dates, now cancelled, Vienna 31st May – 2nd June 2021). New 2020 dates will be announced shortly, in Vienna, probably June 2020.
https://www.phosphorusplatform.eu/espc4
Members of ESPP benefit from a 10% reduction for registration to “Phosphates 2021”, online 23-25 March 2021. This is the only major global event for the phosphate mining, processing, phosphorus chemicals and phosphate fertiliser industries, and brings together over 400 industry participants every year. This year’s Phosphates conference is online, with virtual exhibition and networking centre, interactive discussion groups, conference presentations with Q&A. Registration prices are considerably lower than usual.
https://events.crugroup.com/phosphates/register
FiBL and RELACS are organising five 2-hour webinars to exchange between researchers and Organic Farming stakeholders to gather knowledge on potential risks of use of recycled fertilisers, e.g. organic contaminants, pathogens and microplastics.
Introduction – 3 March 2021, 14h-16h Paris time (CET)
Organic contaminants and other risks, - 11 March 2021, 10h -12h Paris time (CET)
How to recycle nutrients from household wastes and the food industry, 17 March 2021, 14h – 16h Paris time (CET)
How to recycle nutrients from human excreta, 12 April 2021, 14h – 16h Paris summer time (CEST)
Socioeconomic aspects and final discussion , 22 April 2021, 10h – 12h Paris summer time (CEST)
To register, contact:
The call for participants is open to 14th February for the EU R&D EIP-AGRI seminar on healthy soils, 13-14 April 2021. The aim is to share knowledge, experience and innovation concerning on-farm actions to improve soil health, related to productivity, nutrient cycling, water, carbon sequestration and climate change.
Call for expression of interest to 14th February 2021 here.
ESPP has discussed with the European Commission DG SANTE obstacles to nutrient recycling from animal by-products into EU fertilisers. To date, DG SANTE has only requested an EFSA Opinion (European Food Safety Agency) on those animal by-products which are already authorised for use as fertilisers (subject to certain constraints) under the Animal By-Product Regulation 142/2011. This mandate not given to EFSA until May 2020, whereas animal by-products were already an empty box in the EU Fertilising Products Regulation since March 2016 – see ESPP eNews n°50. DG SANTE indicated that EFSA has space to assess (for use in CE-Mark fertilisers) other recycled nutrient products derived from animal by-products, and suggested that industry submit dossiers to EFSA, via Member States. If your company produces a fertilising product from animal by-products, which you wish to be eligible for the CE Mark (under the EU Fertilising Products Regulation), please contact ESPP to discuss possibly preparing a dossier.
The above meeting with EC DG SANTE also concluded that the current regulatory obstacles to recycling of secondary nutrients into animal feeds should be addressed. The EU Animal Feed Regulation 767/2009 (art. 6(1) and Annex III $1 and $5) currently excludes materials derived from manure “irrespective of any form of treatment” or from municipal or industrial wastewater “irrespective of any further processing”. This means that recovering commodity chemicals (e.g. phosphoric acid) from such secondary nutrients is problematic, in that it could be considered that these should only be sold subject to traceability and labelling “not to be used in animal feeds”. It was agreed that ESPP should collate short dossiers from companies operating such recovery processes, summarising possible secondary nutrient inputs, final products, process, contaminants, safety and potential market. The European Commission will then consider possible approaches to this problem. Please contact ESPP if your company wishes to provide input to this.
ESPP made input to the public consultation (closed 18th January 2021) on development of an EU policy for the algae sector. ESPP underlined that the proposed Roadmap did not actively address actively address the important potential for recycling of secondary nutrients and CO2 to feed algae (Circular Economy), that is combining algal production with wastewater and/or offgas cleaning. Algae production is already used full scale to treat municipal wastewaters, in particular for nutrient removal, thus recycling secondary nutrients to feed the algal production and enabling nutrient recovery. Algae can also be used to treat other wastewaters, including digestate. ESPP underlined that use of secondary streams is the only sustainable way to supply the nutrients needed if algae are to be produced large-scale, e.g. for biofuels. ESPP’s consultation input requests actions to clarify the eligibility of waste-grown algae for use under EU fertilisers and animal feed regulations, subject to appropriate safety criteria, and to define safety standards for algae grown on waste streams.
Public consultation “Blue bioeconomy - towards a strong and sustainable EU algae sector”, closed 18th January 2021, contributions consultable here.
ESPP has engaged with IFOAM Organics Europe and the EU project RELACS (Replacing Contentious Inputs in Organic Farming Systems, or Improving Inputs for Organic Farming, see ESPP eNews n°33 and n°40) to identify which recycled nutrient products could be acceptable or desirable as inputs to Organic Farming. The EU Organic Farming Regulation 2018/848 specifies as a principle “recycling of wastes and by-products of plant and animal origin as input in plant and livestock production”. The Organic Farming movement also has concerns about not using input materials which facilitate intensive farming, agronomic behaviour of recycled fertilisers, needs for different nutrients, chemicals used and LCA of recycling processes, possible contaminants. ESPP has submitted, for consideration by IFOAM and RELACS experts, twenty Fact Sheets, prepared by companies operating nutrient recycling processes, presenting product case studies different recycled nutrient products, including ash-recovered materials, struvites, biochars/pyrolysis, P, N, K, S and Fe materials.
A public consultation questionnaire is open on the future EU Soil Strategy to 28 April 2021. ESPP made input to the Roadmap for this consultation in December 2020. ESPP’s input to the current consultation will underline the importance of nutrients and of organic carbon for soil quality and fertility, links to EU water, sewage sludge and Farm-to-Fork policies, the value of recycling of nutrients and organic carbon, and the need to reduce contaminants in secondary nutrient sources (e.g. PFAS, persistent plastics additives, veterinary pharmaceuticals).
EU public consultation questionnaire “Healthy soils – new EU soil strategy”
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12634-New-EU-Soil-Strategy-healthy-soil-for-a-healthy-life
ESPP President, Ludwig Hermann, presented European phosphorus flows, phosphorus recovery possibilities and the SYSTEMIC project at a conference on “Sustainable Nutrient Supply” organised by the Government of the Austrian Federal State (Bundesland) Upper Austria, 9th December 2020, with around 100 farmers and agricultural stakeholders. The presentation addressed the overuse of nitrogen and phosphorus resources, planetary boundaries and EU water quality targets in the context of the European Green Deal and the Farm-to-Fork Strategy. The new EU Fertilising Products Regulation was summarised, and an overview of approaches and techniques for P-recovery and recycling was presented, with success stories from different countries. The presentation will be summarised in an article to be published in April 2021 in the journal “Der Pflanzenarzt”, circulated to 2 500 farmers and agricultural advisors.
Conference recording: https://blickinsland.at/boden-wasser-schutz-tagung-2020/ (in German)
Open to 10 February 2021. See ESPP eNews n°50.
“EU Action Plan Towards a Zero Pollution Ambition for air, water and soil” HERE
Open to 23rd March 2021. See ESPP eNews n°50
Public consultation “IED-EPRTR-Revision-OPC-2020” https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12583-Industrial-pollution-revision-of-the-European-Pollutant-Release-and-Transfer-Register-/public-consultation
The public consultation on the Sewage Sludge Directive is open to 5 March 2021. Key questions concern contaminants and nutrient and organic carbon recycling. See ESPP eNews n°50
Additionally, a targeted stakeholder consultation has been mandated to Trinomics, and information is being collected via specific questionnaires, from wastewater and sludge processing stakeholders, agricultural and consumer associations, academics and experts, NGOs. If you wish to input to this specialist consultation, you should contact Trinomics by email here.
Public consultation on the Sewage Sludge Directive HERE
The International Fertilizer Association (IFA) second phosphogypsum report outlines how to achieve the objective of 100% safe and sustainable use of phosphogypsum (PG), a major by-product of phosphoric acid production from phosphate rock, which in the past has often been stacked as a waste (PG is mainly calcium sulphate, resulting from the reaction of sulphuric acid with phosphate rock). The report outlines quality protocols and regulatory trends for PG use, and presents innovative case studies and country cases. Uses, depending on PG properties, can include agriculture, road building and cement production. PG provides sulphur and calcium to soils and the report presents examples of trials carried out in partnership with science and regulators in Canada (poplar, willow, squash, potato), Russia (rice, soybean, corn, wheat, flax), Kazakhstan (cotton), Morocco (rape, barley, maize). The case of Brazil is presented, where some 10 million tonnes / year of PG are today produced. Agricultural use in the Cerrado region improves the acid soil and provides sulphur, need by soybeans. Brazil now uses all PG currently produced and has started ‘mining’ historic waste stacks, with the objective of depleting these in the coming 7 years or so, enabling return to farming of the land currently used for the stacks.
“Phosphogypsum Leadership Innovation Partnership”, IFA, 2020. HERE.
Prayon, Engis, Belgium, is presented as a case study in the IFA document (above), as the company today recycles almost 100% of its nearly 800 000 t/y of phosphogypsum (PG) production to agriculture (8%) and construction products (production of stucco plaster by Kauf, 92%). This has been enabled by a reengineering of the production process and new purification technologies over recent decades, to generate a clean, quality PG, whilst at the same time increases P recovery rates from phosphate rock, improving phosphogypsum filtration and drying. The PG used in agriculture brings calcium and sulphur, but also retains water. This water retention property has also been shown to enable biodiversity improvement (anthrosol species).
“Phosphogypsum Leadership Innovation Partnership”, IFA, 2020.
The Russia Federal Road Agency has approved hemi-hydrate phosphogypsum (HHPG) as a roadbed material for all classes of roads. This follows R&D led by Phosagro, using both HHPG. Tests show that the pressure on soils is nearly three times lower using HHPG than with conventional granulates, because the HHPG forms a high-strength lightweight slab, spreading pressure and so reducing deformations of road surface materials. The HHPG offers high tensile strength and elasticity, performs well in marshy terrain and is resistant to deformation when frozen. Use of sand and granulates can be reduced by 45 – 75%, so reducing environmental damage from quarrying, and enabling significant cost savings. To date, some 180 000 m2 of road have been build using HHPG, with up to 11 years of road life already.
“Phosphogypsum Leadership Innovation Partnership”, IFA, 2020.
The final EU public consultation on the “STRUBIAS” criteria for struvite and phosphate salts, ash / ash derived materials and biochars and pyrolysis materials is extended to 15th February 2021. It is ESPP’s understanding that this consultation is a formality, prior to official publication of the criteria. The criteria have been discussed at length in the JRC STRUBIAS group and in the EU Fertilising Products Expert Group (ESPP is a member of both). ESPP will input indicating that we support the proposed criteria, which are important for placing on the market of recycled fertilising products and for the roll-out of nutrient recycling technologies, and that the criteria proposed are the result of detailed consultation and dialogue. ESPP will underline the problem that animal by-products (including manures) cannot yet be included in STRUBIAS fertilisers, because DG SANTE has not yet engaged the process of defining Animal By-Product ‘End-Points’ for relevant STRUBIAS materials and has not yet submitted a mandate for this to EFSA. ESPP also regrets that sewage sludge biochars are excluded in the proposed STRUBIAS criteria and reminds of the JRC commitment to further research this question.
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12136-Pyrolysis-and-gasification-materials-in-EU-fertilising-products
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12162-Thermal-oxidation-materials-and-derivates-in-EU-fertilising-products
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12163-Precipitated-phosphate-salts-and-derivates-in-EU-fertilising-products
A public consultation on technical modifications to the Annexes of the EU Fertilising Products Regulation is open to 2 March 2021. As for the STRUBIAS annexes above, this consultation is intended to be a formality, prior to official adoption. The modifications concern traces of substances subject to limits for food and feed (limit values, labelling), clarifications concerning fertilising products which also have a plant protection effect, typologies of micronutrient fertilisers, contaminants in certain growing media, acceptance of natural, biodegradable and soluble polymers (e.g. in processing and handling additives), chelating agents, tolerance rules for labelling, fiberised plant materials, category 2 & 3 animal by products (including manures) in composts and digestates.
Public consultation open to 2 March 2021 “Fertilising products - technical update https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12135-Technical-amendments-to-the-annexes-to-the-Fertilising-Products-Regulation
ESPP coordinated late 2020 a joint letter to the European Commission, DG GROW, expressing a number of questions on interpretation, and industry concerns about practicality of implementation of the new EU Fertilising Products Regulation (FRP). The points raised concern treatment of technical additives in CMCs (Component Material Categories), unreacted processing agents, chemical reactions between additives and CMC materials, and related REACH registration requirements. We have now received a detailed and documented reply from DG GROW. For a number of the points raised, the Commission concurs that questions exist and indicates that clarification will be included in Commission interpretation guidance (FAQ: Frequently Asked Questions document). The Commission’s answer also clarifies for some aspects what actions fertilising products manufacturers need to take with their supply chain to ensure that additives respect FRP-specific REACH requirements.
European Commission “FAQ” for the Fertilising Products Regulation – note that this document is updated regularly - here.
Joint industry letter and European Commission reply here.
The EU Interreg project Phos4You has published several short videos offering overviews of routes for phosphorus recovery from sewage recovery. An ‘Overview’ (1’40) summarises different routes via sludge incineration or from sewage sludge, adapted to both smaller rural or larger urban wastewater treatment plants. Recovery via sludge incineration is summarised for the EuPhoRe process (1’11), where phosphorus is retained in the sludge ash used as fertiliser, tested by Emschergenossenschaft at Dinslaken, Germany, or other processes (presented by Innovatherm, 1’18) where the phosphorus is recovered as e.g. phosphoric acid. Trials of P-recovery via micro-algae or using fishery-waste adsorbents, appropriate for smaller sewage works, are presented (Glasgow Caledonian University, Veolia FiltraflowP, 1’34)
Phos4You videos.
A review of micro-algae in wastewater treatment from Heriot-Watt University, Edinburgh, summarises data from nearly 40 studies. These are essentially laboratory work, with only two using reactors > 1 m3. Most of these studies show, in laboratory conditions, the ability of micro-algae systems to reduce phosphorus to low levels (e.g. < 0.5 mgP/l). Technologies are discussed including algae freely suspended in water, biofilms and algae immobilised in beads. No economic data are provided. The paper concludes that “micro-algae systems incur little or no operational costs”, but this ignores maintenance costs for cell immobilisation, biofilms, membranes, or inputs of light or CO2. A second review from China, summarises different micro-algae strains used, technologies (including diagrams: open ponds, photo bio reactor (PBR), membrane PBR, microalgae film, multilayer bioreactors, …). 11 studies testing with real wastewater are identified, but only one of these provides a cost estimate (0.1 US$/m3 operating costs, Sheng 2017).
“Integrating micro-algae into wastewater treatment: A review”, S. Mohsenpour et al., Science of the Total Environment 752 (2021) 142168, DOI.
“Microalgae-based wastewater treatment for nutrients recovery: A review”, K. Li et al., Bioresource Technology 291 (2019) 121934, DOI.
Two new studies confirm that diets which are good for the environment are also good for health.
Jarmul et al. reviewed literature on the environmental footprint of ‘sustainable’ diets, finding 18 studies (412 data points), covering 12 diet patterns, 7 health endpoints and 6 environmental endpoints. For nearly 90% of data points, sustainable diets showed positive health effects. Sustainable diets showed on average -25% lower greenhouse emissions (-70% lower for vegan diets), but water use (often) and land use (sometimes) were higher for sustainable diets, compared to baseline diets. Phosphorus use was generally estimated to be slightly lower (often reduction less than -10%) for sustainable diets, with nitrogen use showing somewhat larger reductions.
Scheelbeek et al. 2020 analysed real data from 557 722 participants for health outcomes and 5747 participants for environmental footprints from three UK cohort studies (EPIC, Biobank, NDNS), concluding that less than 0.1% adhere to all nine UK Eat Well Guide (EWG) recommendations, but 31% adhere to at least five of these recommendations. Health outcomes were recorded after 3 – 20 year follow-up, and showed 7% reduction in mortality for intermediate/high (compared to low) adherence to EWG recommendations. Environmental footprint was calculated from detailed food data from the participants, and showed that adherence to recommendations led to - 1.5 kg CO2eq/day and - 23 l water use/day.
“Climate change mitigation through dietary change: a systematic review of empirical and modelling studies on the environmental footprints and health effects of ‘sustainable diets’ “, S. Jarmul et al. 2020 Environ. Res. Lett. 15 123014 DOI.
“Health impacts and environmental footprints of diets that meet the Eatwell Guide recommendations: analyses of multiple UK studies”, P. Scheelbeek et al., BMJ Open 2020;10:e037554 DOI.
Within the Phos4You Project (INTERREG VB North-West Europe), Veolia (with the FILTRAFLOTM-P system) and the Environmental Research Institute (North Highland College, UHI, Scotland) are testing processed crab shell waste as a phosphorus adsorbent for tertiary phosphate removal from sewage effluent. Similar approaches have been used previously with other shell and shellfish wastes as P-adsorbents, often after thermal treatment (calcination and sanitisation), including oyster shells (SCOPE Newsletter n°84), mussel shells (SCOPE 89), snail shells (SCOPE 101) and brine-shrimp shells (SCOPE 119).
In this case, the crab shell/carapace (brown crab Cancer pagurus) is washed, dried, milled, then treated with potassium hydroxide to generate a stable, easy to handle, granular material (non-respirable), rich in chitosan and calcium carbonate (see Pap et al. 2020a and 2020b). The material was tested at the Scottish Water Horizons’ Development Centre at Bo’ness (operational WWTP), Scotland, operating a pilot-scale reactor (inflow 200 litres/hour, using between 15-20 kg of adsorbent material) for six weeks (four separate trials) as a tertiary treatment option (on secondary treated discharge). Quality assessment of the saturated adsorbent demonstrated c. 8% organic carbon content dw (total carbon c. 15% dw, part is inorganic) and a 1.1 – 1.3% P dw content, as well as other agronomically valuable components such as potassium (partly from the KOH), calcium, magnesium and chitin/chitosan, with very low heavy metal and organic pollutant levels and no target bacterial pathogens. Future work will involve pot (and/or field) plant growth trials to observe P uptake/availability (starting spring 2021).
FILTRAFLOTM-P crab carapace-based P-adsorbent https://www.nweurope.eu/media/12161/phos4you_p-rich_biomass_en_nov2020.pdf
Trials show that fish bones calcined at 300°C – 900°C are an effective fertiliser. The fish bones were from Round Sardinella (Sardinella aurita) collected from women filleting fish in the port of Saint Louis, Senegal, and were manually separated from offal and heads, then washed and scraped to remove organic tissue. They were then calcined at 300°C, 600°C or 900°C. The lower temperature calcination material contained organic products from collagen and fatty acids, and poorly crystalline hydroxyapatite (HAP), whereas 600°C and 900°C materials showed negligible organics and more crystalline HAP/TCP (tri calcium phosphate). The samples were tested for impact on germination and initial growth of Garden Cress (Lepidum sativum), all showing positive impacts in particular the 900°C material. They were then tested for fertiliser effect in 3-week pot trials with maize (Zea mays), soil pH 6.7. All three samples showed fertiliser effect (compared to control – no comparison was made to commercial fertiliser) but surprisingly the more crystalline 900°C calcined material (with lower solubility) showed higher maize biomass growth. The authors suggest that this may be because of the ‘biostimulant’ effect, as shown on the Cress. A previous paper by the same authors showed biostimulant effects on maize of nano-hydroxyapatite functionalised with humic substances, improving early growth, productivity (3 months), rhizosphere bacteria and salt stress resistance.
“Thermal conversion of fish bones into fertilizers and biostimulants for plant growth – A low tech valorization process for the development of circular economy in least developed countries”, F. Carella, A. Adamiano et al., J. Environmental Chemical Engineering 9 (2021) 104815, DOI.
“Synergistic Release of Crop Nutrients and Stimulants from Hydroxyapatite Nanoparticles Functionalized with Humic Substances: Toward a Multifunctional Nanofertilizer”, H. Y. Yoon, A. Adamiano et al., ACS Omega 2020, 5, 6598−6610, DOI.
A review of available information on phosphine (PH3) suggests that this form of phosphorus may be significant in global P cycles, in waste management and in links to climate change, but concludes that data is today insufficient to reach conclusions. Phosphine is a reactive gas which competes with methane and other reactive gases for hydroxyl radicals in the atmosphere, so prolonging their greenhouse impact. It is oxidised in air to phosphoric acid or phosphate ions, which may contribute to cloud formation, also impacting climate. It is estimated that around 40 000 t/y of phosphine is released to the atmosphere, representing around 10% of airborne phosphorus (to put into perspective: estimates suggest atmospheric deposition of P to the Mediterranean Sea is around half of that from rivers and coastal cities, see ESPP eNews n°43). Phosphine concentrations have been shown to be significantly higher in urban areas, and emissions can be related to anaerobic conditions (paddy fields, manure management, sewage treatment). Phosphate can be reduced to phosphine in redox conditions below -300mV. In specific conditions, up to nearly 20% of P removed from sewage in an oxygen limited membrane reactor was released as phosphine, and the authors suggest that this may be a possible route for P-recovery.
“Global phosphorus dynamics in terms of phosphine”, W. Fu & W. Zhang, Climate and Atmospheric Science (2020) 3:51 ; https://doi.org/10.1038/s41612-020-00154-7
A study based on the McCance & Widdowson Composition of Foods Database, suggests that today’s average UK (meat-eater) diet has P intake of 1.35 gP/day, has decreased since the 1940s (it was around 1.6 gP/person/day in the 1950’s), but could increase if people start to adopt more vegetable intensive diets. Today’s average P intake is significantly lower than a vegetarian (1.53 gP/d = +13%), vegan (1.63 gP/d = +20%) or the proposed EAT-Lancet sustainable diet, see ESPP eNews n°48 (1.85 = +37%). Comparison of the Foods Database to data from UK food surveys suggests that the % of diet P coming from processed (as opposed to fresh foods) has increased from around 20% in the 1940’s to over 50% in 2016, corresponding to a general increase in consumption of processed foods. The % of diet P in animal products (meat, dairy, eggs, fish) increased from around 48% in 1942 to 59% in 1973 and then decreased back to c. 50% by 2016.
The authors found close agreement between the P load entering sewage work, calculated from detailed Environment Agency data, and the dietary P burden calculated from the diet surveys after accounting for estimated industry contributions.
Increased P intake with future sustainable diets and population growth would result in increased P in the inflow of many sewage works. The authors state that this could result in “greater non-compliance with regulatory targets for P discharge” assuming current treatment levels and if treatment efficiency (% P removed) stays constant as inflow P load increases. The view of ESPP, however, is that that for sewage works with a P-discharge consent, increased inflow P will generally not result in increased P discharge, because discharge is managed to respect the consent level (see Evans 2007), although it may result in increased treatment costs (increased chemical dosing, increased biosolids production). It would also result in increased P inputs to the environment in storm overflows. Some large UK sewage works do not today have a P discharge consent, because they do not discharge into eutrophication sensitive* waters. Around 3% of the UK population are not connected to sewerage and a further c. 3% are connected to small sewage works not subject to P discharge consents (figures taken from the study supplementary information p.3). Additionally, not considered in this study, around 3% of sewage is lost in exfiltration from sewage pipes before reaching the sewage works (from Gilmour et al. 2004). That is, in total maybe 10% of sewage is not entering sewage works with P discharge consents, and for this part increased sewage P levels will partly reach the environment and have environmental impacts.
The authors conclude planning and investment should take into account possible increases in P entering sewage works with healthier diets, in order to maximise recovery and recycling of this phosphorus.
“Plant-based diets add to the wastewater phosphorus burden, K. Forber et al., Environ. Res. Lett. 15 (2020) 094018
https://doi.org/10.1088/1748-9326/ab9271
* the EU Waste Water Treatment Directive 91/271/EEC defines (Annex II) Sensitive Areas as waters which are “eutrophic or which in the near future may become eutrophic if protective action is not taken”.
A food system analysis of global agriculture suggests that a complete conversion to Organic Farming would require a “huge” increase in land use ( > +30% ) if other changes in the food system are not made, in particular reductions in food waste and in consumption of animal products. Only 20% conversion to Organic Farming would be possible without increasing land use by more than 5%, without other food system changes. Impact on phosphorus surplus is considered negligible, whereas nitrogen surplus would be completely avoided. However, it is noted that nitrogen supply for Organic Farming is a challenge, which previous authors conclude could only be met if cropping intensities were increased and fallow land and intercropping were to be systematically used for legume production, which may not be possible because of e.g. water supply and feasibility of legume production in intercropping in some regions (see Badgley C et al., 2007, Connor D. et al. 2008 and 2013).
“Strategies for feeding the world more sustainably with organic agriculture”, A. Muller et al., Nature Comunications, 8, 1290, 2017, DOI.
Tests on mice suggest that phosphate nanoparticles can reduce cancer tumours. A colloid of mesoporous amorphous nanoparticles with a very high surface area (Brunauer-Emmett-Teller > 900 m2/g) was produced by reacting Ca, P and citric acid at a ratio of 5:3:5. The particles were then coated in lipid or casein. These particles are non-toxic and release non-toxic molecules if broken down in the body, but can selectively kill cancer cells. The cancer cells take in the nanoparticles, leading to high intracellular levels of calcium and citrate which kills them. In vivo tests confirmed that the coated particles strongly decreased the viability of cancer cell lines, at concentrations down to 30 µg/l, but did not significantly reduce normal cell viability at up to 100 µg/l. Tests with mice showed that the particles reduced the size of two different aggressive pleural tumours by 40% and 70% after two applications, whereas up to eight applications showed no other adverse effects.
“Synergistic Combination of Calcium and Citrate in Mesoporous Nanoparticles Targets Pleural Tumors”, C. von Shirnding et al., Chem 7, 1–15, 2020 DOI.
A paper in Science of the Total Environment by Golroudbary et al. claims in its conclusions that “phosphorus recycling is not a sustainable solution in a longer perspective”. The paper claims to compare energy consumption and greenhouse gas emissions for P-recycling with those from phosphate rock mining and mineral fertiliser production. However, the authors seem to misuse data not relevant for P-recycling, and their conclusions are based on an inappropriate LCA allocation of all sewage works emissions to P-recovery, ignoring the fact that the principal function and obligation of the sewage works is to treat sewage.
LCA allocation factors are not mentioned in the paper, whereas a completely inappropriate 100% allocation factor is given to recovered P, zero to N, zero to clean water.
The authors base their analysis of energy demand for P-recycling on only a few papers, in particular Sanders 2003 (pig manure), Ye 2019 (wastewater, no quantitative data on energy or chemicals use), Piippo 2018 (wastewater, comparison of GHG emissions from different sewage sludge treatment routes in Northern Finland), Spångberg 2014 (wastewater, see below) and Buratti 2015 (solid waste).
They conclude that “70% of the GHG emissions from P-recycling is caused by wastewater processing”. This claims to be confirmed in the paper’s supplementary information, where “Energy requirements for wastewater recycling” are indicated as “179 MJ/0.15 kgP” taken from Spångberg 2014. In Spångberg, it is clear that this energy consumption (179 MJ) is for removing both 1.21 kgN and 0.15 kgP in a sewage works operating chemical P removal, not for removing phosphorus only, and not for recycling these nutrients. Attributing this number only to phosphorus recovery is therefore incorrect. Furthermore, and fundamentally, as the authors themselves point out, sewage treatment and phosphorus removal are in any case necessary for environmental protection. The conclusions comparing energy consumption and GHG emissions for P-recycling from sewage to phosphate rock mining and mineral fertiliser production are thus based on a false starting point.
The use of Sanders 2003 is equally inappropriate. This paper considers the overall LCA of several options for management of pig-manure, mostly assessing nitrogen not phosphorus. Use of this data to draw conclusions concerning emissions related to P-recycling is again incorrect, in that the manure must be managed in any case.
Buratti 2015, used for “solid waste”, is also not appropriate. This paper compares composting of food waste to production of chemical fertilisers for the same nutrient value, but again is not relevant for assessing emissions related to P-recycling because the treatment of the food waste is necessary in any case.
The Golroudbary paper is illustrative in several ways: 17 pages of mathematic formulae will not lead to useful results if inappropriate data and system allocations are used; life cycle analyses can be made to say different things depending how the ‘Functional Unit’ and ‘Boundaries’ are defined and how emissions are “allocated” to different functions; “peer reviewed” does not mean scientifically meaningful.
Note that the above is not in any way a criticism of the different papers cited by Golroudbary. These papers are respectable studies, which do what they claim to do, and their authors obviously cannot be held responsible for their subsequent misuse.
“Environmental sustainability of phosphorus recycling from wastewater, manure and solid wastes”, Science of the Total Environment 672 (2019) 515–524 https://doi.org/10.1016/j.scitotenv.2019.03.439
An assessment (1) based on nearly 1 000 samples comparing vegetation samples in rivers to nutrient concentrations in the Central-Baltic Region of Europe (Belgium, Denmark, Estonia, France, Germany, Latvia, Lithuania, Luuxembourg, the Netherlands, Poland) suggests that nutrient thresholds currently set by some countries are too high to achieve Good Ecological Status (as defined by the EU Water Framework Directive 2000/60/EC = WFD). The authors, led by the European Commission JRC Ispra, looked at both macrophytes (plants) and phytobenthos (bottom vegetation, algae and plants), concluding that both should be considered, compared to soluble reactive phosphorus (SRP), total phosphorus (TP) and total nitrogen (TN). They compared nutrient levels to EQRs (Ecological Quality Ratios), that is ratios between observed data for macrophytes and phytobenthos and expected ‘reference’ conditions (natural state in the water body), with assessment using the methods defined by each country in WFD intercalibration, e.g. density, species or taxon variety. They conclude that thresholds for Good Ecological Quality range from 30 - 90 µg/SRP/l and 1.0 – 3.5 mgTN/l, varying with river size, altitude and alkalinity. These are ln some cases lower that the boundaries set by Member States which range from 70 to 130 µgSRP/l and 2.3 – 10.0 mgTN/l.
A previous paper (2), led by the same authors at EU JRC Ispra, highlights the wide variety of different nutrient criteria used by EU Member States for quality status assessment under the Water Framework Directive, concluding that in some cases inappropriate criteria may be hindering achievement of good status. Different nutrients (N or P) are used for different water categories, whereas recent research shows that co-limitation is not uncommon. Difference in methods (soluble or total N or P, season of assessment, metrics) mean that thresholds are not comparable. Nutrient criteria are in some cases not clearly related to biological response, and so good ecological status. Criteria fixed by expert judgement tend to be higher (less demanding) than those based on data and modelling. Some countries are using thresholds “significantly above” known limiting nutrient concentrations, or even criteria taken from drinking water standards, which are not intended for this purpose.
(1) “Estimating river nutrient concentrations consistent with good ecological condition: More stringent nutrient thresholds needed Ecological Indicators”, S. Poikane (EU JRC Ispra) et al., 121 (2021) 107017 https://doi.org/10.1016/j.ecolind.2020.107017
(2) “Nutrient criteria for surface waters under the European Water Framework Directive: Current state-of-the-art, challenges and future outlook”, S. Poikane et al., Science of the Total Environment 695 (2019) 133888, https://doi.org/10.1016/j.scitotenv.2019.133888
See also: “Deriving nutrient criteria to support ʽgoodʼ ecological status in European lakes: An empirically based approach to linking ecology and management”, S. Poikane et al., Science of the Total Environment 650 (2019) 2074–2084, https://doi.org/10.1016/j.scitotenv.2018.09.350
An interesting analysis of different approaches to nitrogen flow and stock studies for urban areas. Over 60 studies are referenced and information drawn from around twenty of these is outlined and discussed. Nitrogen budget studies in the past have looked at soil systems, at water (river transported N comparing upstream and downstream of a city), atmospheric emissions, human and animal food chain, waste and wastewater treatment. Several studies note that nitrogen fertilisers are often used at very high rates in urban areas, both on lawns and in small farms on crops such as vegetables. Little data was found on nitrogen flows and losses in solid waste treatment. Wastewater treatment showed more significant nitrogen emissions (N2O, ammonia) both to air and to water and often low levels of nitrogen recycling.
Svirejeva-Hopkins, looking at Paris, suggested that the largest N flow was in human food, with around half of this N being finally converted to N2 in wastewater treatment, but the largest environmental impact was from fossil fuel burning, in particular traffic.
Studies, such as L. Baker 2001, suggesting accumulation of N stocks in cities may be flawed.
Several studies for Beijing (Zhang 2016, 2018, 2020) show that total N flows have increased slowly (+1% per year 1996-2012, with N input to farmland and animal feed falling considerably but transport emissions increasing strongly.
Overall, nitrogen recycling rates tend to be very low, e.g. 7% for Bangkok (Faerge 2001). The authors note the difficulty to compare studies, because methodologies differ, and the need to engage with experts beyond scientists to assess relevant flows and processes.
“Urban nitrogen budgets: flows and stock changes of potentially polluting nitrogen compounds in cities and their surroundings – a review”, W. Winiwater et al., J Integrative Env Sciences, vol. 17, n°1, 57-71, 2020 DOI.
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Open to 1st February 2021. The EU has published the final “STRUBIAS” criteria for struvite and phosphate salts, ash / ash derived materials and biochars and pyrolysis materials, prior to adoption and official publication of the criteria.
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12136-Pyrolysis-and-gasification-materials-in-EU-fertilising-products
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12162-Thermal-oxidation-materials-and-derivates-in-EU-fertilising-products
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12163-Precipitated-phosphate-salts-and-derivates-in-EU-fertilising-products
Open to 25th January 2021. ESPP has input to this public consultation (see here) underlining that nutrient recycling is not addressed. The different animal feed Regulations (1831/2003, 767/2009 annex III and 178/2002) currently exclude, from use in production of animal feed additives, any nutrients resulting from processing of manure or wastewaters, even after e.g. incineration, acid extraction from ash and then solvent purification. ESPP fully supports strong safety requirements to prevent any risk of contamination in the animal feed chain, but considers that the blanket exclusion of appropriately processed nutrients poses an unnecessary barrier to nutrient recycling, by blocking added-value markets and potentially preventing sale of recovered nutrients to commodity chemicals markets.
Public consultation: https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12624-Feed-additives-revision-of-EU-rules
Open to 10 February 2021. Public consultation on the EU Zero Pollution Action Plan for air, water and soil, to be adopted in 2021. The Commission’s ‘Roadmap’ outlines as key orientations to: strengthen implementation and enforcement, improve the regulatory “acquis” on health and environment (including water, waste and wastewater), address soil pollution, improve governance and drive societal change / sustainable consumption. The public consultation questionnaire asks for input on questions such as to what extent pollution is felt to be negative, which populations are most exposed, which EU policies are known, which types and sources of pollution should be priorities, possible types of action (regulatory, financial, education, …), significance of digitalisation. “Excess nutrients (nitrogen and phosphorus)” are proposed as one of the possible priority pollutants.
“EU Action Plan Towards a Zero Pollution Ambition for air, water and soil” HERE
Open to 18th January 2021. This Roadmap consultation will prepare possible targeted activities to support the algae sector, maybe including regulatory measures. The document submitted to consultation recognises fertilisers and bio-stimulants amongst different uses of algae and the need of nutrient inputs to algae production. Regulatory gaps cited include limitations to use of algae based animal feeds and fertilisers, and status of algae in the Organic Farming Regulation. Possible regulatory actions cited include binding targets for substitution of fish-based aquaculture feeds. ESPP notes that the proposed Roadmap does not mention the use of algae for waste water treatment (although nutrient removal as an ecosystem service is cited).
Public consultation “Blue bioeconomy - towards a strong and sustainable EU algae sector”
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12780-Towards-a-strong-and-sustainable-EU-Algae-sector
Open to 3rd February 2021. This Roadmap consultation aims to implement the action announced in the EU Farm-to-Fork Strategy on “nutrient profiles” for foods and “mandatory front-of-pack nutrition labelling” for food products. The Farm-to-Fork strategy specifies also an action on ‘maximum levels for certain nutrients’ in processed foods, but this is not mentioned in this Roadmap. The term ‘nutrient’ is here used to cover only “fat, saturates, sugars, salt”. ESPP notes that this will make difficult general public communication concerning the links between plant nutrients (phosphorus, nitrogen …), food sustainability and health. The EU proposal does not consider phosphorus-content of food products, despite the significance of this for kidney disease patients (see ESPP eNews n°34, EFSA new ADI for phosphorus in food).
Public consultation:
“Facilitating healthier food choices – establishing nutrient profiles” = Roadmap for a “Proposal for a revision of Regulation (EU) No 1169/2011 on the provision of food information to consumers”
https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12748-Setting-of-nutrient-profiles-
Open to 23rd March 2021. This EU general public consultation questionnaire addresses emissions from industrial installations, livestock production and pollutant emission monitoring and information, via the Industrial Emissions Directive (IED) and the European Pollutant Release and Transfer Register (E-PRTR). ESPP will input underlining the need to better address the Circular Economy and resource consumption (questions 1, 2, 3, 8, 19, 22, 23); the importance of livestock production (intensive pig and poultry units in question 7, and proposed addition of intensive cattle rearing in question 8). ESPP also underlines that PFAS/PFOS, pharmaceuticals (human and veterinary and microplastics should be added to the E-PRTR substances list, because they pose obstacles to nutrient recycling and the Circular Economy and should be monitored and emissions reduced at source. ESPP also suggests that the E-PRTR list should be automatically updated to be coherent with the Water Framework Directive Priority Substances list (certain pharmaceuticals, HBCDD brominated flame retardant).
Public consultation “IED-EPRTR-Revision-OPC-2020” https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/12583-Industrial-pollution-revision-of-the-European-Pollutant-Release-and-Transfer-Register-/public-consultation
Open to 5 March 2021. Public consultation to support revision of the EU Sewage Sludge Directive 86/278, as promised in the Circular Economy Action Plan. The presentation underlines that the objective is valorisation in agriculture of nutrients, such as phosphorus and nitrogen, as well as organic carbon. The questionnaire is open to individuals, stakeholders and companies and includes general questions about whether the respondent considers sludge use in agriculture to have different positive or negative effects, cost-effectiveness of agricultural sludge application, whether sludge quality is improving and which contaminants are today relevant.
A presentation to the EU Fertilisers Working Group by DG Environment (Caroline Attard) indicated that the evaluation underway of the Sludge Directive will particularly look at nutrient recycling, as well as at methane emissions, impacts of stricter wastewater treatment requirements and pollutants in sewage sludge. A study has been launched into different pollutants in sewage sludge, their sources and risks, possible mitigation according to sludge treatment methods and possibilities for removing pollutants at source. This study will also look at benefits and cost-effectiveness of different sewage sludge use or recycling routes.
Public consultation on the Sewage Sludge Directive HERE
The annual industry conference and exhibition of the world phosphates industry (mining and processing, fertilisers, feed, food, technical applications), CRU Phosphates 2021, will take place online 23-25 March 2021. This conference annually brings together over 400 delegates from phosphate rock mining, processing and different user industries and stakeholders. This year’s online event includes a virtual exhibition and networking centre, interactive discussion groups, conference presentations with Q&A. ESPP members benefit from a 10% discount (on request from ESPP) on the €440 conference fee, which is significantly cheaper than the usual physical conference.
CRU Phosphates 2021 https://bit.ly/386jzjr and events showcase page on LinkedIn
After four years of cooperation, the Phos4You Interreg project’s final conference will focus on : Recovery, processing and distribution of novel phosphorus (P) products; Technologies and processes for deploying P-recycling in urban areas ; Technologies and approaches for enabling P-recovery in remote, rural and island locations; Quality assessment of recovered P materials and LCA-LCC of P-recovery processes. The programme will include plenaries, multi-stakeholders discussions, a poster exhibition, an excursion to a Phos4You demonstrator and plenty of opportunities to enjoy, exchange and network. Speakers will be Phos4You actors in the fields of wastewater treatment and sewage sludge incineration, recovery processes and research. Stakeholders in the agri-food value chain as well as policymakers from EU and national organisations will share their knowledge and engage in discussion
Phosphorus recovery from wastewater: approaches developed within Phos4You, 22-23 September 2021
Essen - Germany & online www.nweurope.eu/phos4you
“The science-based global platform for food system transformation”, EAT is a non-profit founded by the Stordalen Foundation, Stockholm Resilience Centre and the Wellcome Trust. RagnSells (EasyMining’s mother company) organised a session on nutrients as part of the EAT@Home online event.
Pär Larshans, Ragn-Sells and Anna Lundbom, EasyMining indicated the companies’ objectives to maximise recycling, remove contaminants and ensure long-term sustainability of recycling. Sara Stiernström, EasyMining, underlined that EU regulations for both fertilisers and animal feed are based on the origin of input materials, not on the quality of the product, thus posing a fundamental and inherent obstacle to recycling.
EAT@Home https://eatforum.org/event/eat-home/
Watch all sessions at https://youtu.be/Xtzl1eyboEs
Watch the RagnSells session on nutrients https://www.ragnsells.com/eat and to watch https://youtu.be/1Pi1aZ78X30
300 participants (including ESPP President, Ludwig Hermann, as a panellist) joined the IPIFF (International Platform of Insects for Food and Feed) webinar on circularity in insect farming, 19th November 2020. Sabine Jülicher, European Commission DG Santé, indicated that insect production is a relevant component of sustainable food chains. She noted that the use of food waste as feedstock for insect farming will be assessed by EFSA (no timescale yet). Bas Drukker, European Commission DG Agriculture, noted that insects can be used in Organic Farming in some Member States, and that 2021 should see adoption of EU standards for insect production, and consequently for their use as human food and animal feed / aquaculture feed products, as well as standards for insect frass (insect production “manure”). William Clark, Zero Waste Scotland, and Chris Atkinson, IFOAM (EU Organic Farming federation), both underlined the role of insect production in improving local and regional food system circularity.
IPIFF “The European insect sector reaffirms its commitment to supporting the EU sustainability agenda” information 20/2/2020 and webinar recording watch here
SERA-17 is an expert network on phosphorus sustainability in agriculture. The group’s 2020 annual meeting, online 15th October 2020, led by SERA-17 chair, John Kovar, USDA-ARS Iowa, discussed four operational projects underway:
“SERA-17 Meets Virtually to Discuss P” 2/11/2020
ESPP submitted input to the public consultation on the EU Soil Strategy (Roadmap, 8/12/2020). ESPP underlined the importance of soil to food production, climate and biodiversity, and the critical role of phosphorus and other plant nutrients in soil quality and fertility. ESPP noted that the Soil Strategy should include ensuring a fir income for farmers, should contribute to increasing soil organic carbon (including by facilitating return to soil of carbon-rich secondary materials). Problematic contaminants must therefore be addressed at source, in particular PFAS, persistent plastics additives, veterinary pharmaceuticals. ESPP noted the need for EU policy and regulatory support for nutrient stewardship and carbon recycling, including the CAP FaST Tool, addressing obstacles to recycling of manures and animal by-products in the EU Fertilising Products Regulation and progressing recognition of nutrient recycling in Organic Farming.
ESPP input to EU Soil Strategy, 8th December 2020 here.
Despite variable characteristics, all the struvite samples showed similar fertiliser effectiveness, comparable to single super phosphate in 28 pot trials with maize. The authors estimate that around 900 – 1250 tP/y (phosphorus) were recovered as struvite in the EU in 2019. In this study, struvites from 24 European struvite production plants were sampled and tested, from a total of 39 plants identified in Europe (39 sewage works, 9 potato industry, one dairy wastewater). Organic carbon was always lower than the proposed EU Fertilising Products Regulation (FRP) STRUBIAS limit of 3% (and often very much lower) in struvites recovered from digestate or digestate dewatering liquor, but significantly higher for three struvites recovered from secondary wastewater treatment effluent (one of these struvites also showed P content below the FPR limit). Heavy metals were very much lower than the FRP limit. Biological indicators of pathogens were generally low in the struvites, and the data is considered to indicate that the crystallisation process selectively excludes pathogens, leaving them in the water phase. Nonetheless struvites can exceed limits for microbes, and should be analysis. Storage of the struvite causes a reduction in microbe levels. In pot trials, all the struvites gave maize biomass dry weight results similar to single super phosphate (SSP) and significantly better than phosphate rock or control.
“A systematic comparison of commercially produced struvite: Quantities, qualities and soil-maize phosphorus availability”, M. Muys et al., Science of the Total Environment 756 (2021) 143726, DOI.
The QuickWash process, developed for P-removal and recovery from manures by the USDA (see SCOPE Newsletter n°119), is now developed and marketed by Renewable Nutrients. The process has been developed and can now be combined with ammonia removal for pig manure, cattle manure or municipal wastewater. The basic process involves acid dosing and solid/liquid separation, giving a low-P “acid recovered manure” adapted for local land application. Alkali (lime) is then dosed to precipitate and recover calcium phosphate. Polymer dosing improves precipitation to give a low P discharge effluent. A 2020 paper updates on experimental testing of the process for dairy manure. Course solids after the acidification stage are shown to be useable as cattle bedding, and the finer solids as low-P N fertiliser. Renewable Nutrients are now combining Quick Wash with ammonia recovery (as ammonia sulphate). They have also demonstrated the technology at a 7 200 head pig farm in Ohio. Tests have also shown that the technology can be combined with geotextile bag filtration of pig manure lagoon sludge.
Renewable Nutrients – QuickWash https://www.renewablenutrients.com/
“Chemical Extraction of Phosphorus from Dairy Manure and Utilization of Recovered Manure Solids”, A. Szogi et al., Agronomy 2020, 10, 1725; DOI.
The European Commission (DG AGRI) organisation EIP-AGRI has published a short document suggesting themes for “Operational Groups”. These are local innovation/demonstration projects, funded by the EU Rural Development Programmes (1 600 projects funded to date). A number of the proposed themes concern nutrients. This includes those originating in the EIP-AGRI Focus Group on Nutrient Recycling, proposed by ESPP (final report 2017, see ESPP eNews n°18)
“Ideas for Operational Groups and other innovative projects, from Focus Groups experts”, EIP-AGRI, November 2020
Seven Masters students at the University of Amsterdam have prepared input to the European Commission for the future Integrated Nutrient Management Action Plan, announced to be developed as part of the Farm-to-Fork policy in 2021. They propose to develop a “Phosphates Directive” to limit the use of P in agriculture and concentrations in surface waters. Their specific proposals are to fix a mandatory level of recycled P in fertilisers, a tariff on phosphorus imports, lower cadmium limits, addressing legal obstacles to P-recycling , support for P-recycling investments and reducing consumption of meat and dairy (including by investing in meat replacement products, adjusting CAP funding and supporting farmers converting away from livestock). The recommendations are based on a readable 40-page summary of the context, challenges, scenarios and vision, on which the recommendations are based.
Input on the proposed considerations for the EU’s Integrated Nutrient Management Action Plan (INMAP), I. Stammes, T. Maassen, F. Miller Kerins, G. Votano, D. Palma Munguia, Z. Yuan, M. Gereadts, Amsterdam University, June 2020 online here.
A study from the University of Rostock, Germany (ESPP member), assesses policy instruments to make livestock farming compatible with legally binding environmental objectives, including the Paris Climate Agreement, the Convention on Biological Diversity and disrupted nutrient cycles, in particular P and N surpluses resulting from concentrated livestock farming. The study considers a greenhouse emissions cap-and-trade system for livestock farming, and a livestock-to-land ratio fixed to limit greenhouse emissions per hectare. The authors note that the cap-and-trade system has less impact on livestock farmers, allows simpler protection at EU borders vis-à-vis countries not applying similar obligations (by ETS), but might be less effective in addressing biodiversity and nutrient cycles unless combined with a livestock-to-land ratio.
“Land Use, Livestock, Quantity Governance, and Economic Instruments—Sustainability Beyond Big Livestock Herds and Fossil Fuels”, A. Weishaupt et al., Sustainability 2020, 12, 2053, DOI.
The second JRC report on “proposals for by-products as component materials for EU fertilising products” is open for comment to 25th January 2021. The report is available here. JRC proposes to allow use of (only) four classes of by-products under CMC11 of the new EU Fertilising Products Regulation, that is by-products from: fossil fuel refining (but this in fact seems to also include various chemical industry by-products, such as ammonium from caprolactum …), refining of minerals, ores and metals (but phosphogypsum seems to be not included), some gas cleaning systems (but not from waste or manure treatment, see below), processing of biomass, water, food, drink, biorefineries, including from the pulp and paper industries. For ammonia or sulphate salts recovered from cleaning of process gases, the report suggests (pp. 49-50) that these cannot be considered as by-products if there is any waste input into the process. This would exclude nutrient salts from stripping of biogas from digesters processing manure or food waste, or from stripping of municipal solid waste incineration off gases. It should be noted that this report concerns only use of by-products in fertilising products without further processing. If a by-product is used as a chemical reagent then this is eligible for CMC1 (e.g. sulphuric acid recovered from oil refinery sulphur removal from fuels, reacted with phosphate rock to produce phosphoric acid).
“Technical proposals for by-products as component materials for EU Fertilising Products” (2nd report), European Commission JRC, 27th November 2020 here, open for comment to 25th January 2021. Comments must be submitted via a member of the EU Fertilising Products Expert Group. ESPP is a member, so you can send comment to and we will forward them.
The EU Fertilisers Expert Group validated the finalised “STRUBIAS” criteria, which define under what conditions struvite & precipitated phosphate salts, ash-based materials and biochars and pyrolysis materials will be included in the list of materials which can be used in future CE-marked fertilisers (CMC = Component Material Categories of the EU Fertilising Products Regulation). The key principles defined in the JRC “STRUBIAS” report (2019) remain unchanged: phosphate salts recovered from sewage and materials recovered from sewage sludge incineration ash will be eligible, but biochars from sewage sludge will not. Materials not included in the new EU Regulation can nonetheless be authorised in national fertilisers. Manure and other animal by-products (ABPs) of Cat. 2 and 3 can be used as input materials for all three STRUBIAS categories, but only after definition of an ABP “End Point” by DG SANTE/EFSA (see below). Minor wording changes concern interaction with CMC1, frequency of Conformity Assessment audits, bio-waste, definition of waste water, incineration temperature clarification, definition of ash. A discussion concerning sewage sludge in biochars, currently excluded, confirmed that this should be reassessed if new scientific data is developed to demonstrate safety. The finalised criteria will now be subject to a one-month public consultation (in coming months), translation and publication, and will then logically be able to enter into implementation at the same time as the Fertilising Products Regulation itself in 2022.
The European Commission has circulated to Member States and stakeholders, for comments, a table, prepared by ESPP, of secondary materials which cannot currently be used as input materials (CMCs) under the EU Fertilising Products Regulation, and which offer potential for nutrient recycling. This document can be consulted here and comments are welcome, either on the materials listed or proposals for other new CMC materials. The objective is to collect data and to engage discussion with the European Commission to hopefully launch assessment of these and proposal of CMC criteria, although the Commission has indicated that this will not be possible in coming months until other outstanding work is finished finalising and implementing the Fertilising Products Regulation.
Input welcome: “ESPP table of materials currently not included in the FPR as input materials (CMCs)”, v4/11/2020 here
At the EU Fertilisers Expert Group, a representative of DG SANTE was asked to update on progress towards including animal by-products (ABPs) into the new EU Fertilising Products Regulation, which was published in June last year. This is important for nutrient recycling because until the questions around animal by-products are resolved, manure and all other ABPs will be excluded from all CE-mark fertilising products (composts, digestates, biochars, precipitated phosphate salts, …).
CMC10 Animal By-Products, in the published Regulation last June, was an ‘empty box’: after several years of discussion of the draft Regulation, DG SANTE had not provided content, and still today, little progress has been made. This is particularly surprising in that manures and various other ABPs are authorised for use as fertilisers in the Animal By Products Regulation (art. 22 of Regulation 142/2011, that is since nearly ten years ago), subject to specified processing requirements to ensure safety. The difference is that under this regulation 142/2011 these ABP-derived products remain subject to traceability, which would not be the case when included in CE-mark fertilisers under the EU Fertilising Products Regulation FPR (note: this is ESPP’s understanding: ABP regulation is complex and we do not claim to fully understand).
The DG SANTE representative at the EU Expert Group Meeting provided neither slides nor documents, and seemed reluctant to release any information, indicating only that a consultation has been submitted to EFSA (European Food Safety Agency), whose Opinion is necessary before modification of the ABP Regulations. But in fact, the information is public: the mandate requesting an EFSA Opinion is publicly available (enter ‘Mandate Number’ 2020-0088 HERE). This mandate concerns only the following:
ESPP does not understand why it has taken nearly a year after publication of the Fertilising Products Regulation before this mandate was submitted to EFSA, whereas it could have been done immediately or even before publication (ABPs were already an “empty box” in CMC10 in the initial FPR proposal published in March 2016), especially as the mandate simply copies the list of materials already approved for use in fertilisers in the 142/2011 ABP regulation.
DG SANTE provided no answers concerning STRUBIAS materials using ABPs or manure. Similarly, the STRUBIAS process was launched by the European Commission in 2016 and the JRC final report published summer 2019. ESPP does not understand why no mandate on this has yet been given to EFSA.
P-TRAP, a H2020 MSCA-ITN European Training Network – is a consortium of 16 international participants and hosting 11 Early-Stage Researchers (ESRs). A characteristic of these networks is a combined focus not only on science but also on training of a new generation of creative, entrepreneurial and innovative ESRs.
Scientifically, P-TRAP targets two interlinked global problems: I) the flux of phosphate (P) from agricultural areas to surface waters is wasting a resource which is becoming scarce, and II) on the other hand, an enhanced loading of surface water with P is the main cause for eutrophication. Both are in conflict with our understanding of circular economy and a key challenge in meeting the objectives of the EU Water Framework Directive. Within P-TRAP we will develop new methods and approaches to trap P in drained agricultural areas and in the sediments of eutrophic lakes, aiming to constrain the uncontrolled loss of P in one system and preventing others from overloading.
The project is organized in 3 scientific work packages (WPs), which are closely interconnected and each tackling specific objectives and tasks to ensure a successful project.
More information about the project and our participants can be found at https://h2020-p-trap.eu.
Ostara (ESPP member), and the world’s leading producer of recovered struvite from municipal wastewater, has acquired Oakley’s fertiliser granulation facility at St. Louis, Missouri, USA. Oakley will provide full logistic support and storage facilities. Ostara aims to start production of its Crystal Green® continuous release fertiliser at the site within a year, so increasing the company’s production capacity by a factor of ten.
“Ostara and Oakley Sign Letter of Intent for Purchase of Oakley’s St. Louis Granulation Facility”, 3rd November 2020
ESPP’s new member ZSW is looking for partners in the area of phosphorus recovery via incineration / gasification of P-rich residual fuels (e.g. sewage sludge). The not-for-profit Centre for Solar Energy and Hydrogen Research Baden-Württemberg" (ZSW, www.zsw-bw.de), Germany, is looking to participate in consortia or R&D projects into phosphorus recovery via incineration / gasification of sewage sludge or other wastes. The centre can offer testing at a 15 kWth fluidised-bed incinerator / gasifier with flexible feed gas dosing and high-temperature flue / product gas particle separation, as well as analysis of ash melting behaviour with rotational viscometer or thermogravimetry testing, and can contribute to theoretical studies (e.g. modelling and simulation works via IPSEpro, HSC Chemistry, own developed models), in synergy with a current Marie Curie project on P-recovery in fluidised bed incineration (ReCaPHOS, see https://cordis.europa.eu/project/id/842138). Focus on Green Deal Calls and HORIZON EUROPE workprogramme.
If interested, please contact Ms. Dr.- Ing. Glykeria Duelli Varela, tel. +49 711 78 70-319 eMail:
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Within the new Green Deal, the EU's 'Farm-to-Fork’ policy poses ambitious objectives for agriculture – food system sustainability, including to reduce nutrient losses by 50% and fertiliser use by 20% before 2030, to improve nutrient stewardship (revised Circular Economy Action Plan and European Integrated Nutrient Management Action Plan) and to address diet, including via consumer food product nutrition labelling. Horizon Europe also underlines circularity in the food system, and proposes to develop a “comprehensive EU policy to balance nutrient cycles”.
The objective of this webinar is to understand challenges and opportunities for nutrient management in 'Farm-to-Fork' policy implementation and enable dialogue between policy makers, NGOs, industry and professional organisations, scientists and regions/cities.
Friday 27th November, in three parts:
Registrants to the ‘Farm-to-Fork’ webinar are invited to prepare before 23 November 2020 a contribution which be made available to all webinar registrants. ESPP will put online and circulate to all registrants one indexed pdf document containing all contributions received by this date as follows:
Registrants are advised to also prepare a short statement which you can yourself post to the online ‘Chat’ at an appropriate point during the meeting, to link to this submission document and/or your website and/or to other publications. Registrants can also prepare in advance ‘Chat’ questions to submit online during the meeting to the webinar speakers and panellists
Webinar “Nutrients in the EU Farm-to-Fork and Horizon Europe”, Friday 27th November. 2020.
Registration: https://www.eventbrite.co.uk/e/nutrients-in-eu-farm-to-fork-policy-tickets-127743595533
Full programme and speaker updates here: https://www.phosphorusplatform.eu/events
ESPP is planning a webinar with Organic Farming associations across Europe to discuss which types of recycled nutrient products may be acceptable in Organic Farming, in order to then submit dossiers proposing their authorisation in the EU Organic Farming Regulation. Various organic or secondary materials (e.g. certain composts and digestates, plant biochar, certain animal by-products, wood ash) are already included in the Organic Farming Regulation (Annex I of EC 889/2008 as authorised fertilisers). Also, struvite recovered from sewage and calcined phosphates from sewage sludge incineration ash are currently expected to be added (EGTOP Opinion 2 February 2016 here). This webinar will be based on short presentations of various recycled nutrient products “candidates” for Organic Farming, based on discussion of Fact Sheets for candidate recycled nutrient products. If you wish to propose your recycled nutrient product to the Organic Farming movement, and present at this webinar, then you should prepare a Fact Sheet using the template here by 15th December 2020 (to send to ESPP as indicated on the template).
More information here
Open to 10th December. Consultation on an EU Soil Strategy “Healthy soil for a healthy life” (Roadmap), as part of the EU Biodiversity Strategy. Objectives fixed in the Biodiversity Strategy include to stop land degradation by 2030, with action to promote soil fertility, reduce erosion, increase soil organic matter, as well as addressing loss of wetlands and peatland and net land take and sealing. Problems cited include “Diffuse soil contamination by … antibiotics, excess fertilisers, microplastics, sewage sludge …”. Proposed actions include promoting sustainable soil management and improving soil quality monitoring.
Roadmap consultation HERE.
Open to 10 February 2021. Public consultation on the EU Zero Pollution Action Plan for air, water and soil, to be adopted in 2021. The Commission’s ‘Roadmap’ outlines as key orientations to: strengthen implementation and enforcement, improve the regulatory “acquis” on health and environment (including water, waste and wastewater), address soil pollution, improve governance and drive societal change / sustainable consumption. The public consultation questionnaire asks for input on questions such as to what extent pollution is felt to be negative, which populations are most exposed, which EU policies are known, which types and sources of pollution should be priorities, possible types of action (regulatory, financial, education, …), significance of digitalisation. “Excess nutrients (nitrogen and phosphorus)” are proposed as one of the possible priority pollutants.
“EU Action Plan Towards a Zero Pollution Ambition for air, water and soil” HERE
Open to 3rd December 2020. Consultation on product environmental claims & PEFs (Product Environmental Footprints) HERE
Calls for R&D proposals are open to 26 January 2021 on eight themes for the EU Green Deal (total one billion €). The themes include Farm-to-Fork, territorial Circular Economy, climate, biodiversity/ecosystems and zero pollution/toxic free environments.
The call on “Systematic innovations in support of the Farm-to-Fork Strategy” CL-GD-6-1-2020 specifically cites nutrient cycles, antimicrobial resistance and food waste as challenges. Proposals should address one of six proposed objectives including farm carbon sequestration, reducing fertiliser nutrient losses and fertiliser use, shifting to sustainable healthy diets.
The call on “Systemic solutions for the territorial deployment of the circular economy” LC-GD-3-2-2020 should be led by “circular territorial clusters”, bringing together companies, administrations and stakeholders for a “circular systemic solution”. Key product value chains cited are those of the EU Circular Economy Action Plan, including food, water and nutrients.
“European Green Deal Call is open - €1 billion investment in green and digital transition”, proposal submission deadline 26 January 2021 HERE.
Organised by ESPP member MonGos, the first International Conference on Strategies toward Green Deal Implementation - Water and Raw Materials (ICGreenDeal2020) will take place online 14-16 December 2020. Proposals are invited to 30 November 2020 deadline for presentations or posters are invited on environmental engineering and management related to water or raw materials.
ICGreenDeal2020
The journal “Agronomy” (Soil and Plant Nutrition) is calling for papers on "Integrated Nutrient Recovery from Organic Waste and Bio-Based Fertilizers" for a special issue. Submission deadline: 15th December 2020.
The EU has pre-announced a call (to be published mid December) for NGO projects at the Members States’ level to mobilise and strengthen civil society participation and contribution to the implementation of the European Green Deal (under DG ENVI LIFE) EU budget 12 million €, maximum contribution 300 000 € per project.
Growing Media Europe has published, for comment, proposed Life Cycle Analysis methodology guidelines (in accordance with the EU’s PEFCR Product Environmental Footprint Category Rules). Input is invited from stakeholders, industry, LCA experts, e.g. on document structure, methodology, applicability.
“GME draft Guidelines for LCA calculations open consultation”, deadline 14th December 2020 here.
www.growing-media.eu/
It is ESPP’s understanding that all MBM (meat meal, bone meal) may be excluded from use in Organic Farming in a proposed update of EU Regulation 889/2008. The EU Committee for Organic Production, 28-29 October 2020, discussed modifications to the Annex II (authorised fertilisers) of this Regulation to limit animal by-products to only Cat.3, thus excluding* meat meal and bone meal, which are Cat.2, despite they continue to appear in the list of authorised products. This would deprive Organic Farming of a significant source of recycled phosphorus (and potassium). If this is of concern to you, we suggest that you contact your national Organic Farming organisations, and your national Agriculture Ministry. ESPP would be interested in any feedback or information.
* Exact wording added: “animal by-products (including by-products of wild animals) of category 3 and digestive tract content of category 2 (categories as defined in Regulation (EC) No 1069/2009)”
ESPP submitted input to the EU consultation on the E PRTR (European Pollutant Release and Transfer Register), October 2020, supporting the European Commission proposal to improve the register’s contribution to Circular Economy objectives, and suggesting to include data on resource recycling. ESPP also suggested that large cattle production units should be included in the register (which already includes large poultry and pig units). ESPP also supported the proposal to widen the E PRTR to ‘emerging’ pollutants, such as PFAS/PFOS (perfluoroalkyl chemicals) and microplastics.
ESPP input to E PRTR consultation, October 2020 HERE.
DPP (the German Phosphorus Platform) has published a ten page ‘Policy Memorandum’, taking position on key policy and regulatory questions relevant to phosphorus recycling. The document provides information on the current policy status, and makes proposals for policy changes or actions, with the aim of stimulating dialogue and gathering support of stakeholders and decision makers.
The DPP Memorandum notes that major challenges remain to enact German legislation which makes phosphorus recovery obligatory from larger sewage works in Germany (ordinance passed three years ago with implementation deadlines of 2029 / 2032), and that support is needed from politicians and administrations. Sewage sludge could replace around 10% of mineral phosphate fertiliser use in Germany. The German Platform underlines that leadership should be provided to municipalities by Federal and Land governments, including financial support for implementation, funding of R&D and development of Life Cycle Analysis studies and definition of a German nutrient strategy, based on knowledge of nutrient resources and flows (for at least P, N and K). It is noted that, in some cases, regional P-recovery installations are likely to be preferable, in order to reduce costs and optimise costs and improve logistics of recycled phosphorus use, and financial support is needed for construction of large-scale installations.
To facilitate market uptake of recycled phosphorus products, the German Platform considers that economic and market incentives should be implemented by the German government, e.g. by including environmental externalities in prices, quotas for recycled P use (for farmers, distributors and/or the fertiliser industry), subsidies, taxes, bans or use obligations, regulation fixing the same cadmium limits for all fertilisers. It is underlined that better information is needed on recycled nutrient products for farmers, and requested that appropriate recycled phosphorus products be authorised for use in Organic Farming. The German Platform also recommends to remove the current requirements of the national Fertiliser Ordinance (DüMV) on P-solubility and on specification of the origin of input materials, in order to evaluate all products neutrally on the basis of their quality. The German Platform proposes that plant phosphorus availability testing for fertilisers should be standardised and German regulation modified accordingly.
“Politikmemorandum der Deutschen Phosphor-Plattform DPP e.V. 2020 Positionen zur Umwelt- und Landwirtschaftspolitik” (Policy memorandum of the German Phosphorus Platform DPP e.V. 2020 Positions on environmental and agricultural policy), in German, 23 October 2020 www.deutsche-phosphor-plattform.de
The European Commission has published its new “Chemicals Strategy towards a toxic-free environment”, with an accompanying document specifically addressing PFAS (per- and polyfluoralkyl substances). The European Commission’s press release announces the objective to phase out of PFAS in consumer products “unless their use is proven for society”, and this is specified in the Action Plan annex to the Chemicals Strategy by “restrict PFAS under REACH for all non-essential uses”, but also by adding PFAS (as a group) the annexes of the Environmental Quality Standards Directive and of the Groundwater Directive and by “address the emissions of PFAS …through the revision of the legislation on sewage sludge” The document on PFAS states that it would be beneficial that regulation address PFAS as a group, in that regulation of one type of PFAS leads to regrettable substitution by another type. This document also indicates that the revision of the EU Sewage Sludge Directive1986/278 “could provide the opportunity to introduce limits for organic contaminants such as PFAS … including the possibility to have a limit for total PFAS”.
COM document on PFAS (per- and polyfluoralkyl substances) SWD(2020)249
EU Chemicals Strategy, 14 October 2020 COM(2020)667 and annex Action Plan COM(2020)225
In North America, in 2020, Lystek will transform over 1.2 million tonnes of sewage sludge (c. 180 000 t DM) into a “concentrated” liquid fertiliser (15% DM) for agriculture, that is over 3 000 tonnes of phosphorus/year. Dewatered sewage sludge and/or food waste, is thermally hydrolysed (steam injection at 75°C, with alkali addition and physical shearing) for around 30 minutes, sufficient for sanitisation. The resulting liquid can be used as a fertiliser, and/or partly returned to the anaerobic digester (enhancing methane production by up to +25%). The liquid fertiliser is authorised for use in agriculture, depending on State or local regulations in the USA, either as Class A Biosolids or as an agricultural fertiliser product. Depending on the input material (e.g. sewage sludge anaerobically digested or not), the liquid fertiliser has 20 – 40 %/DM organic carbon and typically around 5-2-4 N-P-K. Recent installations by Lystek include St. Thomas - Ontario, Innisfil – Ontario, St. Cloud – Minnesota, Fairfield-Suisun – California, Goleta – California (food waste). www.lystek.com
Earthcare, LLC (USA) is rolling out installations to dry and gasify (at 760 – 1000 °C) organic wastes on an industrial scale, producing a sterile Ecochar® (biochar), which can be used as an activated carbon adsorbent tertiary treatment to remove contaminants such as heavy metals and organic compounds in wastewaters.
The company has seven plants operating to date, each producing c. 4,000 t/y of biochar (Netherlands, USAx4, Russia x 2), and processing pig, cattle or poultry manure, food, fibre or bioethanol plant wastes, and/or animal by-products. An eighth plant with four adjacent gasifiers is underway in Ha’il, Saudi Arabia to process ~60,000 tons broiler chicken litter per year, producing ~17,200 t/y of biochar. Research shows that manure-derived and sewage-derived biochar is highly effective for contaminant removal, probably because of the fixed phosphorus it contains, see Kolodynska 2017.
The heat energy generated by combustion of the syngases has been shown in full scale systems to be sufficient to dry and process sewage sludge dewatered to 20% DM or more.
All of the input phosphorus and 15-20% of input nitrogen is bound into the biochar. The remaining nitrogen is converted to atmospheric N2 (the syngas combustion generates very low NOx) and emissions are filtered by both a chemical scrubber and a bio-bed.
The system is recognised as an agricultural Best Management Practice (BMP) by the US EPA / Chesapeake Bay Program for eliminating the runoff of nitrogen and phosphorus. When the biochar is used to remove organic contaminants from wastewater, it can be decontaminated and reused by thermally destroying the organic contaminants in the triple-pass rotary drum dryer. When the biochar is used to bind heavy metals on contaminated land or in wetlands, it can remain in place, but biochar adsorbing heavy metals at wastewater treatment plants would need to be disposed to approved landfill.
Website https://www.earthcarellc.com/
Contact: Peter Thomas
We reported – incorrectly - in our last eNews results of a Life Cycle Analysis (LCA) of application of N2 Applied’s technology to transform nitrogen from the air with manure or digestate into an organic and mineral fertiliser. The LCA in fact showed that, compared to current practice (as defined by the Arla Foods Farm Tool), N2 Applied technology can reduce greenhouse gas emissions from dairy farming by -36%: anaerobic digestion of manure to produce biogas -16%, N2 Applied alone (treating manure) -27%; biogas + N2 Applied (treating digestate) -36%.
Further information including graphs showing LCA results HERE.
As part of the 18th European week of Regions and Cities, the European Commission organised a webinar on phosphorus recycling from municipal sewage works. 20th October 2020, introduced by Johanna Bernsel and Fleur Van Ooststroom-Brummel.
Chris Thornton, ESPP, summarised different routes for recycling nutrients from sewage, from application of composted or digested sewage biosolids in agriculture, through to “upcycling” where high quality chemicals or fertilisers are recovered and contaminants are removed. Slides here
In discussion, it was indicated that different routes are adapted for different contexts, depending on sewage works size, regional agronomic needs, etc.
Paula Lindell, Helsinki Region Environmental Services Authority (HSY), Finland, explained that the region’s first option for policy is to not incinerate sewage sludge, in order to return the carbon content to soil. Upstream actions to reduce at source contaminants from industrial discharges and form households are important to improve sewage sludge quality. Because iron or aluminium coagulants are used to achieve very low phosphorus discharge concentrations, no existing process is suitable for phosphorus recovery. HSY is therefore developing its own processes for P- and N-recovery (RAVITATM) and is testing pyrolysis (biochar production from sewage sludge).
Lukas Egle, City of Vienna, Austria, explained the city’s overall policy to improve sewage sludge valorisation: development of sludge anaerobic digestion to produce biogas and stabilise sewage sludge, then drying and mono-incineration. Actions underway with the aim of achieving energy-positive incineration and to facilitate phosphorus recovery from the ash include seeking authorisation to incinerate Cat.1 animal by-products (MBM meat and bone meal, which has both high energy content and high phosphorus content), reducing sand (filters) and substituting iron precipitants. Testing is at an advanced stage for use of the sewage sludge (mono)incineration ash in the fertilizer industry to partially replace phosphate rock in fertiliser production. However, intake of ash into this process is limited by sand (silica) and the iron present in the ash.
Challenges posed by the waste status of sewage sludge were discussed. Some progress has been made with the allocation of a specific waste number for sewage sludge incineration ash, which is thus recognised to be Non Hazardous. It may also be possible to have End-of-Waste status by self-declaration if the ash is used “to substitute a raw material”.
Caroline Attard, European Commission DG Environment, indicated that a prospective study on recycling and waste status is underway in the context of the evaluation of the Sewage Sludge Directive.
Robert Van Spingelen, Ostara, indicated that the Ostara has 22 Pearl struvite P-recovery reactors operating worldwide in sewage works. In all cases, the water company has an offtake contract with Ostara who ensure distribution and marketing of the Crystal Green® branded struvite fertiliser product.
He underlined the environmental benefits of struvite recovery in sewage works: lower greenhouse emissions (see struvite recovery “emergy” in ESPP eNews n°35), contribution to reductions of P and N discharges from sewage works, lower in-field nutrient losses. Agronomic research by Ostara shows that because the struvite pellets do not burn plant roots and only release nutrients as required by the plant, higher yields and lower nutrient losses can be achieved. In photos of trials, roots are shown to grow to cover the struvite granules. Tests show that organic acids are released by plant roots and solubilise the nutrients in struvite. The phosphorus is thus only released when the plant needs it and will take it up.
EU 18th European Week of Regions and Cities webinar “Recovered phosphorus from municipal wastewater” 20th October 2020: online here and link to replay video
The EABA (European Algae Biomass Association) online workshop, 7th October 2020, opened by Jean-Paul Cadoret, Algama Foods and EBEA, enabled discussion and networking between 90 participants around the different value contributions of macro- and micro-algae to agriculture and the food chain. Algae can be applied to soils as harvested (e.g. dried) or after cell-lysis, or can be processed to extract specific substances, so as fertilisers, soil improvers or biostimulants.
Vince Ördög, Széchenyi István University, Hungary, presented review data showing that microalgae can increase soil nutrient content by nitrogen fixation, enhance growth of beneficial PGPR (Plant Growth Promoting Rhizobacteria) and release antimicrobial compounds against soil-born plant pathogens. Algae have been shown to produce many different plant hormones. Auxins and polysaccharides produced by microalgae have beneficial effects including plant growth stimulation, increased chlorophyll content, photosynthesis and ROS (Reactive Oxygen Species) scavenging; and improved plant tolerance against salt and drought stress.
Pi Nyvall Cohen, Olmix Group, presented industry experience processing red and green seaweed to products with fertiliser (nutrient content), soil improver and biostimulant effects. Field tests show that after several years’ application, soil carbon increases, crop root volume is improved, soil microbial biomass increases by up to +40% and mineral fertiliser application can be reduced by 5-10% for nitrogen, -40 kgP/ha, -80 kgK/ha and -50 kgMg/ha. Trials are underway in Brittany testing zero chemical intrant / zero mineral fertiliser production of wheat fertilised with the algal products. Regulatory challenges include acceptance for Organic Farming, and the fact that seaweed collected from deposits on beaches is considered a “waste”, but not the same seaweed collected in shallow water near the beach.
Theodora Nikolakopoulou, European Commission DG GROW, outlined the new EU Fertilising Products Regulation, and its significance in providing a European regulatory status for products such as biostimulants and soil improvers, and in providing “End-of-Waste” status for secondary materials when processed into an EU fertilising product (i.e. in a labelled and conformity assessed product). Maris Stulgis, European Commission, DG MARE, indicated that algae have significant industrial potential and DG MARE is there to help untap the potential of algae for various applications. Kristen Sukalac, Prospero and Partners, outlined the regulatory challenges facing the use of algae and derived components in biostimulants and organic fertilisers under the new EU Fertilising Products Regulation.
Questions in discussion of the EU Fertilising Products Regulation included the need to widen the list of micro-organisms for biostimulants (CMC7, currently limited to four species), the question of why cyanobacteria are excluded (CMC2), whether cell lysis of microalgae is acceptable processing (CMC3) and whether substances extracted from microalgae grown on wastewaters can be eligible for CMC1 (or are they excluded as being waste-derived)?
Gabriel Acien, University of Almeria, Spain, presented a marketing study for algae production (SABANA project 2016-2020 Horizon 2020). Algae production raceways are a proven technology, with commercially operating installations of 5 000 m2 and more. The cost of algae production is higher than their nutrient value for fertiliser, but the economics are different where algae production is used for wastewater treatment. Extraction of substances for biostimulants can provide a higher added value.
Companies participating included:
Research presented included:
EABA “Algae Biofertilizers and Biostimulants” technical webinar workshop, 7th October 2020 https://algaeworkshops.org/algae-biofertilizer-and-biostimulants/
As the IFS webinar of 10th November (70 participants, part of the IFS agronomy webinar series), two R&D projects into nutrient recycling were presented.
Romke Postma, Nutrient Management Institute, The Netherlands, presented the ReNu2Farm project (Interreg) which is looking at potentials for nutrient transfer between regions with livestock production towards crop growing regions. Desk study data compared the nutrient surpluses in some regions with crop needs in others, for N, P and K, and for organic matter, taking into account regional climate, soil and differing crop needs. Conclusions are that even in high manure regions, there is a need for concentrated nitrogen fertilisers to top-up manure nutrient inputs, and additionally for potassium for root crops. In low manure regions, there is a need for N, P and K, and additionally for organic matter for root crops. This should be taken into account when producing tailor-made fertilisers from recycled materials.
Results were presented of a survey of 1225 famers concerning attitudes to use of secondary nutrients (in Belgium, France, Germany, Ireland, UK, Luxemburg and The Netherlands, 2018-2019, carried out by which was performed by CIT, Cork, Ireland). Contaminants were the biggest concern for farmers (heavy metals, plastics, other pollutants, pathogens). Farmers currently using secondary materials underlined the importance of the nutrient ratio, organic matter and price; whereas non-users underlined price, ease of application and certification. Over all respondents, known nutrient content and nutrient ratios corresponding to crop needs were identified as key qualities to enable possible substitution of mineral fertilisers.
Martin Blackwell and Tegan Darch, Rothamsted Research, UK, presented the Thallo / Elemental Digest System process proposed for recycling of abattoir and other wastes, as presented in the PlosONE 2019 paper here. Bones and other Cat. 2 organic abattoir wastes are milled to a fine slurry, then combined with sulphuric acid and a metal catalyst, then pressure sterilised (20 mins. @ 133°C, 3 bars DEFRA method 1), before drying and granulation to produce a slow-release organo-mineral fertiliser (see patent WO2014202986, 2014). It is indicated that other wastes can be added, e.g. calcium phosphate from baby food production, biomass combustion ash or waste from fire extinguisher refilling (the silicones in fire extinguisher material is broken down by the high-pressure sulphuric acid treatment). It is suggested that proposed process offers advantages compared to current recycling routes for Cat. 2 abattoir by products (see EU industry data in “Understanding Animal by-products and phosphorus recycling in SCOPE Newsletter n°122), because on-site processing at the abattoir reduces waste, enables recovery of some materials for the human food-chain in an initial sorting stage, and can be adjusted to produce bespoke fertiliser formulations (including different micronutrients) adapted to local soil/crop needs.
The Thallo product typically contains 6.5% N, 3.1% “acid soluble” P, 3% K, 9% S, 9% Ca and up to 30% organic matter, and also many other elements including e.g. zinc (430 ppm), iron (115 ppm). Results from pot trials (16 weeks, with grass and wheat) were presented, comparing the Thallo product to standard NPK mineral fertiliser and slow-lease N fertiliser. Mostly, plant yields were very similar for the three different fertilisers. The Thallo product showed better yields in sand, presumably because of its organic matter content. Analysis of micro-nutrients in the grown plants showed complexity of results, suggesting interactions between different nutrients and micronutrients present.
International Fertiliser Society (IFS) webinar series: programme, registration, access to recordings of past webinars (free for IFS members) Here
A meta-analysis of 652 phosphorus addition experiments in the field, from 285 publications 1955 – 2017, suggests that 49% of croplands and 45% of natural terrestrial ecosystems are phosphorus limited. Phosphorus inputs increased aboveground plant production by an average of 14% in croplands (compared to no P addition controls), which are often already fertilised, and 35% in natural systems (compared to no P addition controls). The data set covered all continents except Antarctica and wide ranges of precipitation. Soil phosphorus limitation was not restricted to tropical soils, with data showing P limitation in natural systems across Europe and in cropland in Northern Europe.
“Global meta-analysis shows pervasive phosphorus limitation of aboveground plant production in natural terrestrial ecosystems”, E. Hou et al., Nature Communications (2020) 11:637 DOI
A study of farm gate nutrient balances and soil nutrient status in twenty Organic farms I Germany shows wide variability, but a mean phosphorus deficit of -3 kgP/ha (SD = standard deviation ±6). Nutrient budgets were calculated as all inputs (fertilising products, manures, animal feed, seeds, plus estimated BNF = biological nitrogen fixation per crop) minus estimated offtakes in crops and by-products. Losses in leaching/runoff were not considered in the calculation. Mean farm balances for nutrients assessed, other than P, were all positive with wider variation: N = +19 (±26), K = +5 (±28), Mg = +7 (±10), S = +12 (±33). Levels of (extractable) nutrients in soils were not correlated to the nutrient balance for N, K, Mg, S, but were correlated for P. Some 14% of soils across the 20 farms showed extractable soil P below optimal levels (KTBL 2015, VDUFA 2018, groups A or B), 27% optimal soil P (group C) and 50% above optimal (D or E). The authors note that farms with a prolonged past of Organic Farming showed higher risk of P depletion in soils and that reliance on biological nitrogen fixation was linked to soil depletion of both P and K. The authors further conclude that “P and K scarcity (are) a major challenge for Organic farms with high reliance on BNF in the long term”.
“Reliance on Biological Nitrogen Fixation Depletes Soil Phosphorus and Potassium Reserves”, M. Reimer, Nutr Cycl Agroecosyst 2020, DOI.
A life cycle assessment (LCA) was carried out of the Nine Springs municipal wastewater treatment plant (WWTP) in Madison, Wisconsin (38,000 p.e. biological P-removal, biosolids used in agriculture) - with and without struvite recovery. In 2017, the WWTP implemented additional phosphorus release from the secondary (bio-P) sludge before gravity thickening and installed the Ostara Pearl struvite recovery system which operates on the sludge thickening liquor (filtrate). Although there was an increase in influent nutrient concentrations after 2017, resulting in a slightly increased discharge concentrations, the authors note that struvite recovery would generally improve effluent quality by reducing nutrient returns to the WWTP in the dewatering liquors. Taking into account the balance of increased chemical and energy consumption versus the recovery of phosphorus and nitrogen (modelled as an LCA offset for fertiliser value), the environmental impacts generally decreased with struvite recovery implementation. In this case, the net greenhouse impact of adding struvite recovery was a reduction in total emissions for the WWTP of around 1% or approximately 4 gCO2-equ./m3 wastewater treated.
“Environmental impacts of phosphorus recovery through struvite precipitation in wastewater treatment”, M. Sena et al., J. Cleaner Production 280 (2021) 124222 DOI
A report by the SuMaNu project summarises manure management in the Baltic region. Examples of Finland, Sweden, Germany and Poland, with maps, show the uneven distribution of livestock production (and so manure). An overview of different manure processing technologies is provided covering, with estimated investment and operating costs for some: solid-liquid separation, slurry acidification, composting, anaerobic digestion (AD), drying, vacuum evaporation, combustion, pyrolysis, gasification, ammonia stripping, membrane separation, struvite precipitation. For some technologies (AD, thermal drying of poultry manure, pelletisation, combustion, gasification vacuum evaporation) case examples are presented. The report concludes that manure processing is needed to enable storage and transport of manure from livestock intensive regions in the Baltic to crop-growing areas, where fertilisers are needed and nutrients can be used efficiently, but that to date manure processing is too expensive for farmers. It is emphasised that the final product must correspond to farmers needs (e.g. spreading equipment) and that reliable information for farmers on the product’s nutrient content and nutrient plant availability must be available.
See also reports on manure processing technology: Wageningen The Netherlands ESPP eNews n°45, NIBIO Norway 2020 ESPP eNews n°41, Washington State University USA 2018 ESPP eNews n°31, the detailed online data base (costs, farmer assessments …) operated by Newtrient in the USA and the specifications in the EUBAT document for intensive rearing of pigs and poultry (updated 2017)
“Manure processing as a pathway to enhanced nutrient recycling”, report of SuMaNu platform, S. Luostarinen et al., 2020, ISBN 978-952-380-037-3 access.
The phosphorus stock and flow analysis for Northern Ireland (NI) carried out within the RePhOKUs project shows that the agricultural P surplus has increased by nearly +50% since 2008 (8.7 kgP/ha in 2008, 12.3 kgP/ha in 2017). This results from a c. +25% increase in P imported in animal feed (+3.4 kgP/ha increase) and a nearly +50% increase in mineral P fertiliser use (+1.4 kgP/ha). Over the same period, average river SRP (soluble reactive phosphorus) increased by around one third (62% of P-total inputs to waterbodies in NI are estimated to be from agriculture). Considering all inflows and outflows of P to NI, the regional P balance (2017) was +5.5 kgP/person (compared to around 0.6 kgP/person P intake in diet: only c. 10% of the net NI P import – export is actually being eaten). The NI food system “phosphorus use efficiency” is calculated by the authors to be 38% (P in agricultural food products / P inputs to the agricultural system). This low P use efficiency (PUE) is considered to be linked to livestock production. Manure produced in NI contains 20% more P than the region’s total P input needs, whereas only c. 10% of poultry manure is processed (2% of P in all NI manures).
“Phosphorus Stocks and Flows in an Intensive Livestock Dominated Food System” S.A. Rothwell et al., Resources, Conservation and Recycling, online here. A technical summary of the work and results from a subsequent stakeholder workshop can be found here.
Researchers have developed a possible treatment route for cancer tumours using calcium phosphate nanoparticles (c. 100 µm diameter, mesoporous), which can be loaded with antitumour drugs (doxorubicin = DOX was tested) and coated with arginylglycylaspartic acid = RGD (a common peptide responsible for cell adhesion). Multidrug resistance of tumours is the primary cause of chemotherapy failure. The prepared nano calcium phosphate composite (called TCaNG) showed good tumour targeting. Once taken into the tumour cell, as well as delivering the drug DOX, the TCaNG releases calcium which suppresses cellular respiration, so reducing production in the cell of glycoproteins which remove cancer drugs. Glycoprotein production is reduced both by direct inhibition (due to calcium accumulation in mitochondria) and by blocking cellular ATP production (adenosine tri phosphate, necessary for energy cycling) so reducing the effectiveness of the glycoproteins. The TCaNG reduced the proliferation of drug-resistant tumours in mice by a factor of c. 13.
“Nanoenabled Intracellular Calcium Bursting for Safe and Efficient Reversal of Drug Resistance in Tumor Cells”, J. Liu, Nano Lett. 2020, DOI.
The title of a paper in ‘Nature Ecology & Evolution’ suggests that it shows phosphorus fertilisation to “eradicate” threatened plants in northern Europe. The paper is based on data from 16 sites in a few widely separated zones: seven in the band Netherlands – Belgium – Switzerland, five in Eastern Poland / Belarus, one in Sweden, one in Northern Scotland and two in Siberia. The paper shows, for these sites, correlations suggesting that both “availability” of phosphorus to plants and ratio of “available” P/N are more correlated to plant biodiversity and to threatened plant species than N or K. “Availability” is not here based on soil data, but is estimated from above-ground plant biomass nutrient ratios. As authors indicate, this sensitivity to P is to be expected as P is generally the “limiting nutrient” in nature. The authors then suggest that “An EU Phosphate Directive” is needed, based on speculation that reducing P-fertiliser application would reduce P availability in land relevant to threatened biodiversity. ESPP does not see evidence in the paper to support this: it seems likely that reduced P-fertilisation of a field might reduce P levels in land nearby, but it is not clear how reduced P fertilisation would significantly lower P availability in more remote areas (e.g. the Northern Scotland or Siberia sites in the study). Atmospheric phosphorus deposition is never mentioned in the paper, despite N deposition being discussed. Other sources suggest global phosphorus deposition may be quantitatively nearly 1/5th of P annually mined in phosphate rock, but that most atmospheric P deposition comes from natural sources (e.g. dust from deserts, pollen and other biogenic materials), see ESPP eNews n°43.
“Phosphorus fertilization is eradicating the niche of northern Eurasia’s threatened plant species”, M. Wassen et al., Nature Ecology & Evolution 2020 DOI.
Based on data from 7580 respondents in a national eating and drinking study, and analysis of 876 representative food product samples (purchased in supermarkets), it is concluded that average adult phosphorus intake in diet is around 1.2 gP/day, higher in toddlers, and with a small increasing trend with age from children through to the elderly. The phosphate intakes were higher than the AI (Adequate Intake) and lower than the UL (tolerable Upper intake Level), so “no significant risk” to health. The main dietary sources of phosphorus were grains (including rice), fresh meat and poultry and milk products. The authors note that none of these contain phosphate food additives. Calcium intake in adults is around 0.5gCa/day, compared to an AI of 1 gCa/day for adults, so are considerably too low.
In a separate study in the city of Shiraz, Iran, based on a dietary survey of 438 persons and analysis of 580 food samples from shops and markets, phosphorus intake is estimated at only 0.21 gP/day, considerably lower than the EAR (estimated average requirement) of 0.58 gP/day. Calcium intake was 0.24 gCa/day, again much lower than the EAR of 0.8 gCa/day. For both phosphorus and calcium, around 90% of the population had intakes below the EAR. Whereas sodium intake was 1.47 gNa/day compared to an EAR of 1.5 gNa/day. 70% of the population had sodium intakes higher than the UL of 2 gNa/day.
“Risk Assessment of the Dietary Phosphate Exposure in Taiwan Population Using a Total Diet Study”, M-P. Ling et al., Foods 2020, 9, 1574, DOI.
“Dietary Intakes of Zinc, Copper, Magnesium, Calcium, Phosphorus, and Sodium by the General Adult Population Aged 20–50 Years in Shiraz, Iran: A Total Diet Study Approach”, E. Babaali et al., Nutrients 2020, 12, 3370, DOI.
By Jim Elser and Phil Haygarth, this new book, 250 pages, presents phosphorus’ roles in biology, human health and nutrition, ecosystems and in environmental sustainability. The importance of mined phosphate rock to global food production is explained, and the environmental problems generated by phosphorus losses to surface waters. Phosphorus sustainability efforts are presented, with solutions and possible future scenarios.
“Phosphorus: Past and Future, J. Elser & P. Haygarth, publication 1st January 2021, ISBN 978-0199916917
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Open to 26 October 2020. The E PRTR Regulation (EC) 166/2006 ensures that certain pollution emission data is made public. It currently covers emissions of 91 listed pollutants for installations in 65 sectors. Listed pollutants include nutrient emissions (total P, total N, ammonia). Confusingly, coverage is not the same as for the Industrial Emissions Directive IED: 30 000 installations in Europe concerned by the PRTR but 50 000 by IED. Sectors covered at present by PRTR include waste and wastewater treatment (whereas municipal sewage works* are not under IED), slaughterhouses, food and beverage industry, large poultry and pig farms (same thresholds as IED, see below) but also aquaculture which is not covered by the IED (> 1 000 tonne fish or shellfish per year). The consultation on the PRTR considers possible widening of scope, additional pollutants (e.g. to emerging pollutants), collecting information relevant to decarbonisation and the Circular Economy and improving public information access. ESPP notes that the E PRTR pollutant list currently does not include a number of substances on the Water Framework Directive “Priority Substances” list: PFOS and its derivatives, a number of pharmaceuticals, brominated flame retardant HBCDD
* i.e. those covered by the Urban Waste Water Treatment Directive 91/271/EEC
EU public Roadmap consultation on the European Pollutant Release and Transfer Register (E PRTR) open to 26 October 2020 HERE
Open to 29 October 2020. The “EU Action Plan Towards a Zero Pollution Ambition for air, water and soil” stems from the Green Deal objective of zero pollution (see ESPP eNews n°39). The consultation document refers to pharmaceuticals, persistent and toxic chemicals and micro-plastics. It notes that pollution to soil should be addressed and is not well covered by existing EU regulation.
EU public Roadmap consultation on the Zero Pollution Ambition open to 29 October 2020 HERE
Open to 27th October 2020. See ESPP eNews n° 47. Consultation HERE
Open to 22nd October 2020. See ESPP eNews n° 47. Consultations here on water, on habitats, landscapes and biodiversity, and on sustainable management of soil.
Open to 3rd December 2020. Consultation on product environmental claims and PEFs (Product Environmental Footprints) HERE
The European Commission has published the 4th version of the Critical Raw Materials List (CRM). Phosphate Rock (in effect, phosphorus in any form: rock, fertiliser, chemicals, organics ….) and “Phosphorus” (in effect, P4 and derivatives) are maintained on the list. This new list is the previous 2017 list plus four minerals (bauxite, lithium, titanium, strontium). The Commission announcement recommends inclusion of CRM investments in Covid recovery plans, development of recycling and domestic sourcing of CRMs, actions on value chains and international trade. The accompanying document identifies EU dependency on imports (84% import dependency, of which Morocco and Russia total 44) for phosphate rock and for P4/derivatives (100% import dependency, of which 98% from Kazakhstan, Vietnam and China). Overall emphasis in the short term is strongly on the “rare earth and magnet value chains”, identified as relevant for renewable energy, defence and space. An accompanying study by EU JRC assesses CRMs relevant for “strategic technologies”, identified as: lithium ion batteries, fuel cells, wind energy, electric traction motors, photovoltaics, robotics, drones, 3D printing and digital technologies. Unfortunately, this study does not consider “Phosphorus” (P4 and derivatives), which is almost totally absent from the study (e.g. absent from the conclusions and study cover Sankey diagram, which covers 24 other materials). Also, in Annex 2 to the European Commission official CRM List Communication, Phosphate Rock and Phosphorus are indicated as relevant to “Energy intensive industries” (bizarrely) and “Agri-food” but not to other sectors where P-based chemicals are important: renewable energy (e.g. in batteries), digital (e.g. microchip etching), electronics, aerospace (e.g. flame retardants). ESPP will write to the European Commission to address these omissions.
European Commission Communication COM(2020) 474 final, 3rd September 2020 “Critical Raw Materials Resilience: Charting a Path towards greater Security and Sustainability” HERE
JRC “Critical Raw Materials for Strategic Technologies and Sectors in the EU – A Foresight Study”, 2020, ISBN 978-92-76-15336-8 HERE
The European Commission has published its evaluation of the Industrial Emissions Directive which regulates over 50 000 installations in Europe, including food and dairy processing, waste treatment and large poultry and pig farms (replacing several Directives including IPPC). The evaluation is based on input to stakeholder consultations (see ESPP eNews n°42, ESPP input submitted here). Conclusions are that the Directive is effective, cost-efficient, coherent and provides EU added value. Amongst aspects which work less well or are to be addressed, the Commission identifies resource use and Circular Economy, greenhouse gas emissions, implementation of BAT technologies, emerging technologies and possible widening of scope. The report states that a few highly-polluting activities are not currently covered by the Directive, including cattle farms, aquaculture and poultry farms below the current IED threshold of 40 000 birds, but notes that extending to cover cattle farms has previously been considered and rejected because of the administrative burden.
“Executive Summary of the Evaluation of the Industrial Emissions Directive (IED)”, European Commission SWD(2020)182 (Executive Summary) and SWD(2020)181 full report, 23 September 2020. The executive summary(182) is available by searching here. The full report (182) seems to not be publicly available at present but can in fact be found here.
Perfluorinated alkyl chemicals are a contaminant found in sewage sludge which raise particular concern (see SCOPE Newsletters n° 134, 129, 123) but which could be avoided if their use was restricted. The EFSA (European Food Safety Agency) Opinion covers PFOA, PFOS, PFNA and PFHxS (collectively termed PFAS). They are used in e.g. textiles, household products, fire-fighting foams, automotive, food processing, construction, electronics. EFSA indicates that there is evidence that these chemicals are bio-accumulative and are probably linked to reduced immune response, cholesterol, liver impacts, infant birth weight, with limited evidence of carcinogenicity. EFSA has fixed a TWI (tolerable weekly intake) of 4.4 nanogrammes/kg body weight (total PFAS substances).
“PFAS in food: EFSA assesses risks and sets tolerable intake”, EFSA press release 17 September 2020 and EFSA Scientific Opinion adopted 6 July 2020 “Risk to human health related to the presence of perfluoroalkyl substances in food”.
The European Environment Agency (EAA) has published a briefing document on biodegradable, compostable, bio-based and oxo-degradable plastics. This underlines the differences between these different categories: bio-based = fully or partly made from biological raw materials, but may or may not be readily degradable; compostable = in some cases in industrial composting systems (with controlled conditions), in other cases also in less well controlled garden composting; biodegradable = in natural media (soil, water …) but with no recognised standard for testing conditions, and degradability in soil may not mean degradability in water; oxo-degradable = include additives which cause breakdown into microplastic particles or chemical decomposition. This vocabulary is not well understood by the public: in one survey in Germany, nearly 60% thought bioplastic implied biodegradable. The report suggests that marketing of plastics as “biodegradable” or “compostable” may need to be prevented to reduce consumer confusion and misuse of such plastics, but that such plastics can be useful in specific applications (e.g. bags for household separate collection of food waste or agricultural mulches), subject to respecting precise standards adapted to the specific application.
“Biodegradable and compostable plastics challenges and opportunities”, European Environment Agency, Briefing 9/2020
John Bell, Director “Health Planet” at the European Commission DG Research, underlined that planetary boundaries are considerably exceeded for phosphorus and nitrogen and that urgent and systemic action is needed. Mark Sutton, International Nitrogen Initiative, underlined that both all nutrients need to be addressed, but that nutrients tend to be forgotten. He underlined the economic significance: nitrogen losses represent some 200 billion US$ fertiliser value worldwide, and societal a further 70 to 320 billion US$. That is in total, in Europe, around 1/3 of the CAP budget. He welcomed the proposed EU objective to halve nutrient pollution by 2030 in the Farm-to Fork strategy which echoes the United Nationals Environment Assembly resolution EA.4 (march 2019, see ESPP eNews n° 33). Chiara Manoli, ECOFI, underlined the progress made in organic fertilisers, with standardisation of production processes. This enables recycling of nutrients and carbon in secondary materials such as wine or food processing wastes, poultry litter from egg production, fish meal, residuals from tanning, etc., and brings organic carbon to soil, contributing to soil fertility and to water retention. She underlined the importance of the new EU Fertilising Products Regulation which puts in place, for the first time, EU criteria for organic fertilisers, but notes that outstanding regulatory difficulties remain with Organic Farming and with Animal By-Products. Jannes Mes, President of the European Council of Young Farmers, underlined that farmers are motivated to reduce nutrient pollution, but cannot fund actions to improve nutrient management without public support.
EU R&I Days 2020: 22nd September 2020, webinar with Katja Klasinc and John Bell, European Commission, Mark Sutton, International Nitrogen Initiative, Chiara Manoli, ECOFI and Jannes Maes, European Council of Young Farmers (CEJA) watch online
A session at the prestigious American Association for the Advancement of Science (AAAS) annual symposium, 8th February 2021, will address how phosphorus losses to surface waters can accelerate greenhouse gas emissions, and how climate change can feed back to accentuate eutrophication, with John Downing, University of Minnesota, Laura Johnson, Heidelberg University and Ahren Britton, Ostara. This is supported by the ESPP – US Sustainable Phosphorus Alliance joint SCOPE Newsletter special issues on nutrients and climate change: methane emissions (SCOPE Newsletter n°135); P runoff, catchment management and P in soil (coming soon); P and soil health links to climate; greenhouse emissions of nutrient management and recycling (both planned).
Phosphorus and Climate Change: A Vicious Circle, AAAS Annual Symposium, 8th February 2021, 12h – 12h45 ET https://meetings.aaas.org/
The annual DPP Forum, 24th September 2020, took place as a hybrid event with 135 participants (75 in Frankfurt). Presentations covered questions concerning the implementation of the German Phosphorus Recycling Ordonnance, status of development of P-recovery projects and installations in Germany, industry requirements and experience in processing recycled nutrient materials, and farmers’ expectations concerning recycled nutrient fertilisers. The specific requirements of the Organic Farming movement for recycled P products were discussed, including safety, life cycle analysis and of use of chemicals in processing. The Forum also discussed a proposed DPP Memorandum under preparation to propose actions to politicians to move forward phosphorus recycling.
German Phosphorus Platform (DPP) annual Forum 2020.
The two-day annual North America phosphorus event this year was two three-hour webinar sessions, with over 70 Participants worldwide.
Struvite recovery
Chris Hornback, National Association of Clean Water Agencies, underlined the need for federal clarification of the status of struvite recovered from sewage plants. The EPA enacted in 2017 that struvite could be authorised case by case*. * ESPP note: For example, Ostara CrystalGreen struvite is authorised in 42 US States (see SCOPE Newsletter n° 124).
Aaron Fisher, Water Research Foundation, underlined the advantages of struvite precipitation in reducing P in biosolids, reducing polymer use in dewatering and improving dewatering (higher dry matter content of biosolids).
Robert van Springelen and Matt Kuzma, Ostara, presented application of the company’s Crystal Green PEARL® struvite recovery to phosphate rock processing water, both in operating installations and in leachate from phosphogypsum ‘stacks’ at closed sites. A pre-treatment step removes fluoride and silica using lime. After struvite precipitation and membrane finishing, the treated process water can achieve discharge water quality. The technique and process is in TRL 9 stage and proven successful in full scale.
Manure phosphorus
Rebecca Muenich, Arizona State University, underlined that manure is a major nutrient pollution challenge and the biggest potential source for P-recycling in the USA. There is no national inventory of CAFOs (Concentrated Animal Feeding Operations) or AFOs in that many do not have federal environmental permits*. R&D work is underway to develop a virtual mapping of AFOs and CAFOs across the USA based on remotely-sensed data. * ESPP note: the US EPA AFO web pages indicate that < 7 000 out of nearly 21 000 AFOs with numbers of animals above thresholds requiring NPDES permits did not have such a permit in 2019). The thresholds are equivalent to c. 700 dairy cows, 2 500 pigs or 125 000 broiler chickens. The EU requires permitting (under the Industrial Emissions Directive) from 2 000 pigs or 40 000 poultry (but not yet for intensive cattle installations).
Jeff Dawson, Renewable Nutrients, indicated that the company now holds the licence to the USDA QuickWash® process (see SCOPE Newsletter n°119). The enables P recovery from manure by acid solubilisation followed by calcium phosphate precipitation and can be combined with ammonia recovery using a gas-permeable membrane.
Rick Johnson, Applied Environmental Solutions, indicated that livestock farms face increasing manure management costs. NRC 590 limits spreading of phosphorus per hectare, so increasing manure transport distances and costs. P-recovery from manure can reduce the hectares needed for manure spreading by as much as 40%
An opportunity for the future was identified as mobile manure processing units, to enable cost-sharing between farmers.
Perspectives for nutrient management
Kerry McNamara, OCP, outlined the company’s actions to maximize phosphorus sustainability across its entire value chain, and to support sustainability at the farm level. We have to make nutrient stewardship economically sustainable for farmers. OCP is committed to optimal use and recycling of phosphorus, as part of the company’s overall sustainability objectives, which include 100% clean energy and zero non-renewable water use by 2040 and carbon neutral by 2040, as well as maximizing P recovery at all stages of its operations. As one example of that, OCP is currently exploring Ostara struvite recovery technology for its own processing discharge in Morocco, and also possibilities for phosphorus recycling from municipal sewage works.
Don Boesch, Maryland Center for Environmental Science, summarised actions to restore the Chesapeake Bay since the 1980’s. Objectives for nutrient input reductions fixed for 2000 and 2010 were not met. Mandatory TDMLs (Total Maximum Daily Loads) are now set for 2025, but reductions are likely to again fall short. Nutrient loads have been reduced since the 1990’s and smaller hypoxic areas are now seen in the Bay, but nutrient levels are not falling as fast as management models indicate. This could result from “lag time” due to P remobilisation from soil and sediments and nitrate storage in groundwater, but it could also be that agricultural nutrient BMP measures (Best Management Practices) are not being implemented as they should be, or that they are less effective than assumed. On the other hand, there seems to be more urban nutrient retention than management models estimate.
Agricultural nutrient loss models and their implementation
Carl Bolster and Barret Wessel, USDA-ARS, summarised work ongoing assessing models of farm nutrient runoff in the West Lake Erie Basin (TBET and Apple models). The objective is to be able to model losses by field, as a function of agricultural practice, with a model which uses available data and which is accessible to extension agents. Model results show high levels of uncertainties, and a challenge is how to identify these and how to communicate uncertainties to users.
Jon Winsten, Winrock International (a large non-profit organisation addressing agricultural, environmental, and social issues around the world) summarised test programmes in Ohio, Vermont, Wisconsin and Iowa. Farmers are paid for quantified outcomes, calculated for actions intended to reduce nutrient losses. Payments are, for example, c. 80 US$/kg P loss reduction, c. 11 US$/kg N, based on modelling, on a field by field basis. The models show very high variations between fields. Winrock provides farmers with field-by-field calculations of modelled nutrient loss reductions, of resulting payments, of estimated costs (e.g. income loss for land converted to buffer strips), and helps farmers find the most cost-effective actions.
Sustainable Phosphorus Alliance annual forum 2020 – watch online.
This webinar organised by EasyMining discussed possibilities for recycling phosphorus, iron/aluminium and silica sand recovered from sewage sludge incineration ash.
Dines Thorberg, Biofos (Copenhagen public water company), indicated that farmers are sceptical about possible value of sewage sludge incineration ash as a P-fertiliser, and zinc and chrome levels are too high for land application. Ash produced today has c. 10%P (dry weight), and Copenhagen has a landfill of 350 000 tonnes of sludge incineration ash from the past with average c. 5% P. In the past, part of the ash was recycled into mineral wool construction materials. Biophos is currently tendering to find a process to recover phosphorus from the sludge incineration ash.
Yariv Cohen, EasyMining, indicated that the company’s Ash2Phos process (see ESPP P-Recycling Technology Catalogue) enables recovery of c. 90% of phosphorus and c. 80% of calcium are recovered from ash as quality grade calcium phosphates. 60-80% of aluminium and 10-20% of iron can be recycled to sewage works as coagulants. Higher levels of iron could be recovered, but at a higher cost and chemical consumption, whereas there is at present no regulatory or market driver. Over 95% of heavy metals are removed, leaving a clean silica sand material which can be used in concrete production. A 30 000 t(ash)/y Ash2Phos plant will generate c. 13 000 t/y of calcium phosphate product and 23 000 t/y of silica sand.
Cement production has high climate emissions (5 – 8% of anthropogenic GHG), so partial replacement with this silica sand could be very attractive to cement companies and could bring climate offset income.
Lisbeth Ottosen, Technical University of Denmark, summarised testing of EasyMining recovered silica sand to replace cement in concrete production. Kg-scale trials have shown that 20% of cement in concrete can be replaced by recovered silica sand, on condition that it is briefly milled (10 seconds) and with use of plasticisers to improve concrete quality. The resulting concrete has a reddish colour (iron in the silica sand) which can have aesthetic advantages, and shows only a small loss of strength. Further research is needed to understand the chemistry of cement phases, to optimise plasticiser use and to test durability of the resulting concrete over time.
Katrine Orland Led, Ramboll, outlined conclusions of a market analysis study into use of silica sand to replace cement in concrete. Interest of the cement industry to reduce climate emissions could be a driver. Potential applications include facades, pre-fabricated concrete structures, ground stabilisation, binding layers, paving stones and fibro-cement materials.
“Value adding recycling of sewage sludge in concrete. Making concrete more sustainable”, EasyMining webinar, 2nd October 2020, available here https://www.easymining.se/article-startpage/sustainable-concrete-webinar/
Crop P needs in soils with “legacy phosphorus” were discussed as part of the IFS agronomy webinar series, with Sophie Nawara, currently working at the Soil Service of Belgium (the presented research was part of her PhD study at KU Leuven). Much of Europe had a highly positive soil P balance from the 1940’s (phosphorus application as mineral fertiliser and/or manure greater than crop offtake and runoff). There has been a decrease in phosphorus fertilisation in Western Europe over the last decades, and Western Europe’s overall P-balance is negative since around 2000 (from Fig. 5 in Zhang et al. 2017, see SCOPE Newsletter n°128). However, the over-fertilisation during decades has caused an accumulation of soil P (“legacy P”) resulting in current high soil P contents in some regions in Europe.
Two year greenhouse trials were carried out with eight different Flemish soils, using rye grass (fast growing, needs rapid P supply). Results showed that, in this specific case and after two years of P “draw down” by the rye grass, legacy P in soil alone (without addition P fertilisation) led to a significantly lower cumulative biomass than with P fertilisation in six out of eight of the soils, when adequate nitrogen was supplied, see Nawara et al. 2018.
Modelling suggests that a fast reacting P pool (e.g. adsorbed P in soil) can be accessed sufficiently rapidly by crops, but that legacy P is more present in a slow reacting P pool (e.g. into soil particles with ageing), which is only slowly accessible to plants. Fast growing plants experience P deficiency faster than slowly growing plants because of their higher P demand rate which exceeds faster the soil P supply rate.
Also some soil P tests were evaluated in their capacity to predict crop yield in a P depleting scenario. None of the soil P tests outperformed the others, meaning that, for European soils, the crop accessible P is generally well measured by the Olsen-P (0.5M NaHCO3) test and by the ammonium lactate soil test, both which are often used as standard soil P tests.
International Fertiliser Society ( IFS) webinar series: programme, registration, access to recordings of past webinars (free for IFS members): HERE
Data from ongoing trials of different secondary or recycled P fertilisers materials were presented in the IFS agronomy webinar series, with Patrick Forrestal, Teagasc, Ireland. National testing in Ireland in 2019 (n=30,466) show that around ¾ of Ireland’s soils need P applied to meet crop off-take (Index 1, 2 and 3 under the Irish system). Half of soils (in Index 1 and 2) also need P application to fill soil P sinks to be raised to the agronomic optimum (Index 3).
Seven different bio-based P materials were compared to control (no fertiliser) and TSP (triple super phosphate) in field trials in 2019 (results presented) and 2020 (ongoing): two struvites, cattle manure slurry, chicken litter ash, sewage sludge incineration ash, dairy residues complexed with aluminium or calcium. Ireland produces some 140 000 t/y of P-rich dairy processing residues. Soil was Index 1 and pH was limed to 6.1. Phosphorus was applied at 60 kgP/ha/year was applied, as per agronomic recommendations with four grass cuts per year.
Control with no P application showed only 40% of the yield with TSP. Yields were broadly similar for all the bio-based materials and for TSP.
For P-uptake, which is significant because it impacts P levels in grazing cattle diets, struvite and slurry shows, in results to date, P uptake somewhat higher than for TSP, poultry litter ash and Al-complexed dairy residue similar to TSP, and sewage sludge incineration ash and Ca-complexed dairy residue somewhat lower.
These results should not be considered conclusive, and statistical analysis will be completed when the 2020 field trial results can be also included in the dataset.
Limerick collaborators showed that certain soil P solubilizing bacteria are more active with bio-based fertilisers than with TSP. Higher P uptake with struvite, compared to TSP, may be because slower P release from struvite could be an advantage in this field setting where soil is competing to fix available P while crop uptake is progressing.
This work is funded by the EU Interreg project ReNu2Farm and the EU H2020 project Nutri2Cycle. International Fertiliser Society ( IFS) webinar series: programme, registration, access to recordings of past webinars (free for IFS members): HERE
Lab tests were carried out on sludges resulting from post-precipitation of phosphates from the Viikinmäki municipal sewage works, Helsinki: coagulant dosing downstream of secondary treatment, followed by disc filtration (RAVITA process, see SCOPE Newsletter n°132). The RAVITA sludges were precipitated using either iron or aluminium coagulant and were tested as received (11 – 14% DM) or after incineration (550°C for 2 hours). Leaching with phosphoric acid was done in previously optimised conditions: 0.5M acid, 6 hours for aluminium; 2M acid, 1 hour for iron. Results showed c. 85% extraction from sludge and 99% from ash for aluminium; but only c. 37% from sludge and 68% from ash for iron. Approx. 95% leaching of phosphorus was achieved with both ashes, but no data is given for P leaching efficiency from the sludges (because of water content). The higher leaching of P compared to Fe or Al suggests that a significant part of these elements is not bound to phosphorus. The authors note that with aluminium, the leached P is mainly as soluble phosphate, whereas with iron, most is as soluble FeH2PO42+ ions, so that further processing would be necessary to separate the phosphorus from the iron. Heavy metals were analysed in the RAVITA sludges and found to be low, but it is not clear whether this is because they are retained in the secondary sludge or whether the Helsinki sewage has lower heavy metals than generally in Europe. The authors conclude that incineration of the RAVITA sludges improves potential for recovery of P and of Fe/Al. However, this may not be practical because the organic content of these post-precipitation sludges is low.
“To incinerate or not? Effects of incineration on the concentrations of heavy metals and leaching efficiency of post-precipitated sewage sludge (RAVITATM)”, S. Reuna, A. Väisänen, Waste Management 118 (2020) 241–246, DOI.
On 21st September, ESPP member N2 Applied opened a new nitrogen recovery unit production hall, with Raymond Robertsen, Norway State Secretary of Regional Development and Erik Solheim, former UNEP Director and Norwegian Minister, and Ola Hedstein, CEO of Norwegian Agricultural Cooperatives. N2 Applied’s plasma technology uses air, electricity and manure slurry to create an organic and mineral N containing fertiliser which has no odour, reduced emissions and higher nitrogen content. Farm installations fit into a haulage container. An LCA study by 2.-0 LCA indicates that a combination of digestion of manure to produce biogas and N2 Applied technology can reduce greenhouse gas emissions from dairy farming by -36% (compared to baseline): anaerobic digestion of manure to produce biogas -16%, N2 Applied alone (treating manure) -27%; biogas + N2 Applied (treating digestate) -36%.
A process to remove and recover phosphorus from wastewater from the production of the antibiotic, Fosfomycin (1R-2S-epoxypropyl phosphonic acid), was tested at the lab scale. The wastewater contains, in particular, high levels of antiobiotic, preventing biological treatment, refractory organophosphorus chemicals, solvents and the complexing agent EDTA. A thermal process (wet air oxidation WAO, 200°C, oxygen @ 1 MPa, pH 11.2, 3 hours) converted 99% of organic phosphorus into soluble inorganic phosphate and removed nearly 60% of COD. Phosphorus was then removed and recovered from the liquor (which had nearly 1 000 mgP/l) by precipitation of calcium phosphate or struvite, achieving in appropriate conditions over 99% P removal and residual phosphorus below 5 mgP/l. The precipitated phosphates showed low heavy metal levels, but organic or pharmaceutical residues would need to also be verified. The treated liquor was suitable for biological treatment.
“Phosphorus recovery from fosfomycin pharmaceutical wastewater by wet air oxidation and phosphate crystallization”, G. Giu et al., Chemosphere 84 (2011) 241–246, DOI
The German Federal Research Ministry (BMBF) has published stage two results of its RePhoR = Regional Phosphorus Recycling call for projects. The call was published in February 2018 and consisted of two stages: a “concept” stage, and an “implementation” stage.
19 projects were selected in stage 1, which funded the preparation of “regional P-recycling and sewage sludge reuse strategies” (leading to a 25-page document). These are listed on page 343 of this document (article by Helmut Löwe, BMBF.
The list of projects now published corresponds to the second stage of this call, that is those selected to “receive funding for the implementation of the concepts”. The call states that these should be “large-scale implementation of … processes” and specifies “exemplary development and large-scale implementation of processes for P recovery under real conditions for different plant sizes and types (at least TRL 6 for short)”.
However, some of the seven selected projects nonetheless appear to be R&D scale and to not correspond to the large-scale process implementation specified in the call.
RePhoR, Germany, regional phosphorus recycling joint projects, September 2020 https://www.bmbf-rephor.de/verbundprojekte/
RePhoR launch event and internal workshop, 3rd & 4th November 2020 https://www.bmbf-rephor.de/veranstaltungen/rephor-kick-off-seminar/
Several papers present tests ongoing in Poland (Wroclaw, Olsztyn, Puławy) solubilising phosphorus secondary materials using 7-day culture with microorganisms, granulating the resulting material, and then testing in field trials. Secondary materials used in the different tests reported are ground bio-P-SSIA (sewage sludge incineration ash from a sewage works operating biological P-removal), ground bones (cooked chicken or fish bones), MBM (meat and bone meal ash). Microorganisms tested include Bacillus magaterium, a large, rod-like, Gram- positive bacteria, naturally occurring in a range of habitats, and widely studied, and used in industry (to produce penicillin amidase, used to make synthetic penicillin) and Acidithiobacillus ferrooxidans [a] Bacillus cereus, Bacillus subtilis and Bacillus thuringiensis (results not yet published).
For example, in a 2019 paper [b], at 30 litre batch reactor lab scale, with bio-P-SSIA and poultry bones as substrates, pH in the culture fell to c. 4-5 within one day, then was relatively stable. P in the culture solution increased after 7 days during B. magaterium culture from near zero to c. 200 mgP-PO4/l for sewage sludge incineration ash or over 600 mgP-PO4/l for poultry bones, that is c. 9% for ash and 23% of total P in the materials. Around 100% of the P in ash and was found to be extractable (with water or citrate) after 7 days.
Granulation has been tested [c] at semi-technical scale (c. 100 kg/h capacity batch plate granulator), after drying of the whole culture at 60°C for three days, thus retaining the P in the culture solution, using various granulation agents: dried blood, superphosphate, bentonite, gypsum, sodium lignosulphonate, molasses.
The granulated micro-organism-activated materials (based on bones and sewage sludge incineration ash) have been tested in four field trials in Poland with winter and spring wheat, showing fertiliser effectiveness similar to phosphate rock and to a low-medium dose of superphosphate (18 or 26 kgP/ha) but lower that a standard agronomic recommendation dose of superphosphate (35 kgP/ha) when comparing to the same dose of P in the recycled fertiliser material [f].
Contaminant levels in the produced recycled fertilisers were low with bones, but up to 22 mg/kg for lead, 0.8 mg/kg for cadmium and 880 mg/kg for copper (from sewage sludge incineration ash). However, application at c. 35 kgP/ha resulted in no detectable change in levels of cadmium or lead in soil or in crops grown [d].
Assessment in the field trials also showed that the use of these recycled fertilisers did not modify number, biomass or species composition of earthworms [e].
[a] Valorization of Phosphorus Secondary Raw Materials by Acidithiobacillus ferrooxidans, M. Wyciszkiewicz, A. Saeid, et al., Molecules 2017, 22, 473; DOI: 10.3390/molecules22030473 and Valorization of ash and spent mushroom substrate via solid-state
solubilization by Acidithiobacillus ferrooxidans, A. Saeid & A. Patel, Waste Management 87 (2019) 612–620, DOI: 10.1016/j.wasman.2019.02.048
[b] Production of phosphorus biofertilizer based on the renewable materials in large laboratory scale, M. Wyciszkiewicz, A. Saeid, et al., Open Chem., 2019; 17: 893–901, DOI: 10.1515/chem-2019-0057
[c] Obtaining granular fertilizers based on ashes from combustion of waste residues and ground bones using phosphorous solubilization with bacteria Bacillus megaterium, M. Rolewicz et al., J Env Management, Volume 216, 15 June 2018, Pages 128-132 DOI: 10.1016/j.jenvman.2017.05.004
[d] New phosphorus biofertilizers from renewable raw materials in the aspect of cadmium and lead contents in soil and plants, M. Jastrzebska, A. Saeid, et al., Open Chem., 2018; 16: 35–49 DOI: /10.1515/chem-2018-0004
[e] Phosphorus Fertilizers from Sewage Sludge Ash and Animal Blood Have No Effect on Earthworms, M. Jastrzebska et al., Agronomy 2020, 10, 525; DOI:10.3390/agronomy10040525
[f] Fertiliser from sewage sludge ash instead of conventional phosphorus fertilisers? M. Jastrzebska, A. Saeid, et al., Plant Soil Environ., Vol. 64, 2018, No.10, 504–511 DOI : 10.17221/347/2018-PSE
OceanForesters are looking for partners, supporters or for other technologies to include, for a project for the United Nations Decade of Ocean Science for Sustainable Development. The project will target “Nutrient Recycling Seafood Science”.
United Nations Ocean Decade. ‘Nutrient Recycling Seafood Science’ project page on the United Nations Decade website. Contact Mark Capron, OceanForesters.
Modelling of P inputs to and losses from cropland suggests that soils are losing 2 kgP/ha/yr on average worldwide (-1.5 for Europe). Worldwide, the study estimates that arable land is depleted of c. 6.3 MtP/y (1.5 lost in organic P and 4.6 lost as inorganic P). This compares to estimates of losses ranging from c. 1 to 18 MtP/y in other publications. Soil P depletion is worst in Africa and Eastern Europe. The authors estimate that around half of this worldwide soil P depletion is due to soil erosion by water, concluding that agricultural management practices to reduce soil erosion are important to reduce soil P depletion.
“Global phosphorus shortage will be aggravated by soil erosion”, C. Alewell et al., (2020) 11:4546, DOI: 10.1038/s41467-020-18326-7
A modelling study published in the British Medical Journal (Springmann et al. 2020), publicised in the media (see e.g. The Guardian), compares national governmental food based dietary guidelines in 85 countries, WHO dietary recommendations and the EAT-Lancet Commission on Healthy Diets from Sustainable Food Systems 2019 recommendations (see ESPP eNews n°30). Based on country-specific data, impacts were compared to internationally agreed objectives on greenhouse gas emissions (Paris), health (Action Agenda on Non-Communicable Diseases), freshwater use, land use (Aichi biodiversity targets), nitrogen and phosphorus fertiliser application (planetary boundaries). Adoption of current national dietary guidelines would result in an overall reduction in premature mortality of 15% (obesity, heart disease, etc) and a similar reduction in greenhouse gas emissions. However, most of the national guidelines are not adequate to achieve the internationally agreed environmental or health objectives. The EAT-Lancet recommendations would deliver around 1/3 more reduction in mortality and around 3x more reduction in greenhouse gas emissions than the national guidelines.
Below: extracts from fig. 5 page 9 of the paper.
The analysis concludes that adoption of national dietary guidelines worldwide would not significantly modify global use of phosphorus and nitrogen fertiliser (slight increase in P consumption, near zero decrease in N consumption). This is not shown in extracts above where only Europe is shown, see fig. 5 page 9 of paper. This is because increased fertiliser use for fruit, vegetable and dairy production offsets reduced demand for staple crops (grains, potatoes), meat and sugar. In Europe, however (see extracts above), adoption of national dietary recommendations leads to around -10% reduction in N and P consumption, mainly because of reduced pork and staple crop consumption.
At the global level, adoption of the EAT-Lancet recommended diet would lead to significant (c. -10%) reduction in phosphorus use, and an even higher (c. -15%) reduction in N use, again mainly because of reduced consumption of pork and staples (grains & potatoes), despite the increases resulting from consumption of fruit & vegetables, oils, nuts & seeds.
The authors note that national dietary guidelines generally recommend an increase in dairy consumption (see extract figure for Europe above) whereas EAT-Lancet recommends to reduce dairy to one serving or one glass of milk per day. They also note that reducing dietary calory intake, particularly associated to staple crops and sugar, is significant in reducing phosphorus and nitrogen use, whilst also reducing health risk from obesity.
ESPP notes that the impacts on P and N use seem to differ significantly from the impacts on greenhouse gas emissions, in that the latter are principally driven by red meat consumption (which also drives health impacts) whereas P and N use are not mainly driven by red meat consumption. Also, adoption of national dietary recommendations leads to increased GHG emissions in all regions worldwide, whereas it appears to lead to reduced P and N use (fig. 6, page 10 of the paper). ESPP underlines, especially for P, that the results of this paper are based on other publications’ estimates of e.g. impacts of meat production on overall phosphorus use, which probably need further research, so that although the direction of conclusions is clear, further research is needed for quantification.
In an earlier study (2018), Springmann et al. modelled increases in environmental impact from the food system by 2050 resulting from world population and income increases, concluding c. 50% increases in phosphorus and nitrogen use and c. 90% increase in greenhouse gas emissions. Whereas changes in diets alone are estimated to potentially (with most ambitious scenario) reduce future GHG emissions to below current levels and close to respecting planetary boundaries, diet changes are estimated to have much lower impact on N and P use. On the other hand, technologies, including improved fertiliser and animal feed use, water basin management and manure management, alone, are estimated to potentially reduce P use below current levels and within planetary guidelines, and are also the measure with the highest mitigation potential for N use. The authors conclude that a combination of dietary change, technologies and reductions in food loss and waste is necessary to avoid increased environmental pressure from the food system and to enable respect of planetary boundaries.
“The healthiness and sustainability of national and global food based dietary guidelines: modelling study”, M. Springmann et al., MJ 2020; 370: m2322 DOI
See also the EAT-Lancet Commission on Healthy Diets from Sustainable Food Systems 2019 in ESPP eNews n°30
“Options for keeping the food system within environmental limits”, M. Springmann et al., Nature volume 562, pages519–525(2018) DOI
This Horizon 2020 project is now running for 2 years and aims to improve agricultural nutrient use efficiency whilst reducing greenhouse emissions, protecting soil carbon stocks and addressing the social, economic and political dimensions. The project looks at practices including seeding, type and application of recovered fertilisers, dairy cow feed composition and manure derived fertigation. Nutrient recovery techniques including vacuum degassing and struvite precipitation without addition of chemicals are tested.
Despite difficulties related to Covid and to irregular weather conditions, the six case studies have already generated valuable results:
- Catalonia (Spain): precision feeding of cows reduced N concentrations in urine by 40% without impairing milk production.
- Brandenburg (Germany): low rainfall can lead to overapplication of up to 50 kg/ha N
- Lungau (Austria): above average (6,480 l/ha) milk yields in Organic Farming in the Austrian Alpes
- Emilia Romagna (Italy): fertigation by sub-surface drip lines with ultra-low N emissions and crop yield and energy (fuel) use advantages of sod-seeding (minimum tillage) of winter wheat
- Gelderland (the Netherlands): demonstration of struvite, not only as P fertiliser, but also as an effective N fertiliser with very low N2O and NO3 emissions compared to urea, and that digested pig slurry has much lower N2O emissions than raw slurry for the same crop yield. Perennial grass types, alone or in combination with clover can also have a significant impact on N emissions but clover monocultures should be avoided.
- Moravia (Czech Republic): whey from dairies can be used as nutrient carrier whereas dosage and application still need to be determined.
https://www.circularagronomics.eu/
Twelve pharmaceuticals were detected in pig manure and slaughterhouse sludge in Catalunya, Spain. All twelve were found in manure, at concentrations up to 6600 µg/kg in the solid fraction (for doxycycline, a tetracycline antibiotic used to treat pneumonia, Lyme disease, cholera …), and most were found in the slaughterhouse waste. Both these 12 pharmaceuticals and five ARG (antibiotic resistance genes) were measured through a processing plant handling c. 7 000 t/y of manure and 11 000 t/y slaughterhouse sludge with an anaerobic digester (mesophilic, 75-80 days, producing biogas), followed by solid/liquid separation (centrifuge) and finally reverse osmosis (RO) of the liquid digestate. Mass balances for the pharmaceuticals were calculated based on measured concentrations and flows. Results are complex, in that for some periods/substances the flow of pharmaceuticals out of the anaerobic digester seems to be higher than that in the inlet (negative removal). This could be explained by several factors, such as the collection of the samples within the same day and to some analytical constraints (i.e. matrix effects). Overall, the anaerobic digester very significantly removed macrolide antibiotics (tilmicosin, tylosin), somewhat removed flubendazole and flunixin, but did not generally remove (except in some specific cases) lincomycin, fluoroquinolone or tetracycline antibiotics. In solid/liquid separation, most of the pharmaceuticals were retained in the solid fraction (except lincomycin and tiamulin), with sorption not being correlated to logKow values. The RO membrane however generally removed up to 90% of the pharmaceuticals. For ARGs, reduction was also limited in the anaerobic digester, little or no reduction in solid/liquid separation and again significant reduction through the RO membrane.
“Fate of pharmaceuticals and antibiotic resistance genes in a full-scale on-farm livestock waste treatment plant”, M. Gros et al., Journal of Hazardous Materials 378 (2019) 120716, DOI
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The EU has opened a public consultation on EU Strategic Guidelines for Aquaculture, open to 27th October 2020. The current Guidelines (COM(2013)229) are misleadingly titled “Sustainable Development of EU Aquaculture), whereas in fact they address only competitivity (simplification of licensing, marketing, level playing field) and facilitating implantation (spatial planning). ESPP submitted to the prior Roadmap consultation suggesting to include nutrient efficiency of aquaculture feed and nutrient footprints (making the link to the nutrient strategy proposed in Horizon Europe) and underlined the need to reduce nutrient losses from both offshore and fresh water aquaculture and to develop nutrient recycling. Sustainability and fish feed do appear in the short online questionnaire for the current consultation.
EU consultation on aquaculture HERE
The European Commission has opened, to 22nd October 2020, three public consultations on the impacts of EU agriculture policy on water, on habitats / landscape / biodiversity and on sustainable management of soil. The objective is to assess the impacts of the CAP (Common Agricultural Policy), as per the 2013 reform, which includes the obligation for farmers (condition of subsidies) to respect mandatory rules (“cross-compliance”), including both statutory management requirements (SMR) and standards of good agricultural and environmental conditions (GAEC). Additionally, there exist voluntary agri-environment-climate measures (AECM) and subsidies for farmers in areas subject to natural constraints (Natura 2000, Water Framework Directive restrictions). The consultation consists of a public questionnaire asking whether respondents consider that the CAP contributes to different environmental objectives and questions on effectiveness or unintended consequences of CAP measures.
EU public consultations open to 22nd October 2020 on the impacts of the Common Agricultural Policy on water, on habitats, landscapes and biodiversity, and on sustainable management of soil.
An Eu public consultation is open to 3rd December 2020 on “Substantiating claims of environmental performance for products, services and businesses”. This targets PEFs (Product Environmental Footprints) but also addresses ecolabels, greenwashing, environmental performance reporting, sustainability ratings, harmonisation of environmental information. The consultation aims to respond to the aim of establishing “labelling on the sustainability performance of food products” announced in the Farm-to-Fork Strategy. The announced objective is to identify policy options for substantiating environmental claims using Environmental Footprint methods. The online questionnaire addresses, in detail, what types of environmental claims should be authorised and under what conditions, how environmental footprint results should be communicated, how claims should be verified (conformity assessment).
EU consultation on product environmental claims and PEFs (Product Environmental Footprints) HERE
This EU annual event (this year virtual, 22-24 September 2020) aims to make links between policymakers, researchers and stakeholders to shape the future of R&I in Europe. The event’s ten virtual ‘hubs’ include Green Deal, Missions and Horizon Europe. The programme includes, 22 September Green Deal Hub: 12h45-13h30 Uncrossing Planetary Boundaries: How to get nutrient flows back within safe ecological limits? and 14h-15h Workshop on Circular and Bio-based: towards a carbon neutral and sustainable economy
Programme and registration here
An interview of the chair of this Horizon Europe R&D “Mission”, Cees Veerman, suggests that the Mission seems to have changed its name to “Caring for soil is caring for life” and that there now seems to be now no content directly addressing food (other than that healthy soil is important for food production). The Mission now seems to be entirely orientated towards soil quality. (other than that healthy soil is important for food production). A short and confidential consultation (not announced on the EU’s public consultation website, 1st to 14th September 2020 only) HERE and #MissionSoil called for ideas for this Mission inviting submission of up to 5 short idea “proposals” (actions, priorities) to address soil health, and inviting to vote on proposals already on line. An interview of chair of the Mission Board, Cees Veerman, indicates that the Mission seems to have changed its name to “Caring for soil is caring for life” and there now seems to be now no content directly addressing food in the mission, which seems entirely orientate towards soil (other than that healthy soil is important for food production).
Online consultation HERE and #MissionSoil
To replace the annual Cambridge agronomy conference, the International Fertiliser Society (IFS) is organising a series of webinars, to February 2021, covering themes such as P availability and depletion in soil (2nd October), fertilisers from recycled materials (10th November), digital tools and soil nutrient sensors, accurate fertiliser application, nitrogen fertilisation of cereals, soil boron, …
“Phosphorus (P) availability during the depletion of soil P”, Sophie Nawara, Fien Amery, Hilde Vandendriessche, Roel Merckx and Erik Smolders, Friday 2nd October 14h00 CEST
“Exploring variations in demand for fertilisers derived from recycling in NW Europe” and “New developments in the production of plant-available phosphorus from abattoir waste”, Romke Postma, Martin Blackwell, Tegan Darch, Tuesday 10th November 14h00 CEST
Full details of IFS webinar series (programme and registration): HERE
Organised in the framework of the 11th Annual Forum of the EU Strategy for the Baltic Sea Region (EUSBR), with SuMaNu and BSAG, this workshop will discuss input to the HELCOM Regional Nutrient Recycling Strategy to be adopted in 2021, including eutrophication mitigation, manure management, Circular Economy and links to climate change. Breakout groups will address markets for recycled fertiliser products, cooperation in P management in the Baltic region and reducing contaminants in sewage to ensure safety of recycled nutrient materials;
Webinar workshop: ““Unlocking the nutrient recycling potential in the Baltic Sea Region” (SuMaNu – EU SBRS):
30th September 2020, 13h-15h30 CET – programme and registration
HELCOM Regional Nutrient Recycling Strategy: see presentation by Marja-Liisa Tapio-Biström.Finland Ministry for Agriculture, at the 12th HELCOM Meeting of the Working Group on Reduction of Pressures from the Baltic Sea Catchment Area 21/4/2020 HERE
The SPA’s annual Forum is this year virtual, 30th September and 1st October, 12h-15h00 EST. This year’s programme addresses regulation of recycled nutrient products, nutrient recovery operation, climate change and eutrophication, pay-for-performance nutrient pollution mitigation, phosphorus transport modelling …
Sustainable Phosphorus Alliance Forum 2020, 30th September and 1st October, 12h-15h00 ET (New York time) on both days. HERE.
The Sustainable Phosphorus Alliance Phosphorus Transport Modeling Group brings together researchers and practitioners to discuss use and improvement of soil, water and watershed P transport models, such as Annual Phosphorus Loss Estimator Tool (APLE) or Soil and Water Assessment Tool (SWAT). The group’s second meeting in late 2019 identified the need to cross-validate models, to integrate across scales and to compare with real edge-of-field P runoff data.
Sustainable Phosphorus Alliance Phosphorus Transport Modeling Group HERE and summary November 2019 meeting HERE.
The University of Seville is interested in samples of iron (II) phosphate (vivianite), which can form spontaneously in sewage works or in anaerobic digesters, for pot and field fertiliser tests. The objective, part of the EU-funded P-TRAP project, is to assess whether this form of iron phosphate can provide plant available phosphorus or iron to crops.
Contact
The University of Vienna is looking for biostimulant products possibly able to release phosphorus from iron in soils (certain ligands, humic substances, siderophores …) for testing. As part of the EU-funded P-TRAP project, the objective is to identify products or chemicals which can be used to improve the fertiliser value of secondary materials containing iron phosphates (e.g. iron materials after use in phosphorus traps, sewage sludge from works operating chemical P-removal), or to deliver to crops in a combined fertilising product containing both iron phosphate (possibly as iron (II) phosphate, vivianite) and an iron-accessing biostimulant.
Contact
The UK & Irish water industry’s joint research organisation, UKWIR, has joined ESPP. UKWIR is the national research organisation serving all the water companies in the UK & Ireland. Our members are the 19 water companies of England, Scotland, Wales, Ireland and Northern Ireland. Our research covers the whole managed water cycle and aligns well with the activities of ESPP in a number of key areas. In particular, how do we maximise recovery of useful resources and achieve zero waste?. Also, how will we deliver an environmentally sustainable wastewater service that meets customer and regulator expectations?. Maximising recovery of phosphorous from wastewater, and limiting its use in the treatment and distribution of potable water, are real challenges for the water industry as a whole, here and world-wide. UKWIR is therefore keen to collaborate in new research projects through ESPP and learn from ESPP’s member organisations and network both in Europe and around the world.
www.ukwir.org
As part of the LIFE ENRICH project (ESPP member), a Life Cycle Analysis study compares two scenarios for struvite recovery before anaerobic digestion in a sewage works operating biological phosphorus removal (EBPR) in the Murcia-Este WWTP, Spain. In the first scenario WAS (waste active sludge) is thickened using dissolved air flotation and fermented during 24 h to maximize poly-P release then elutriated in gravity thickeners with primary sludge. Struvite recovery from the overflow was modelled, considering different thickening and mixing rates. In a second scenario, WASSTRIP-based phosphorus release was modelled: primary sludge was fermented to generate volatile fatty acids then mixed with WAS in anaerobic P-release tanks and the resulting soluble-P enriched solution, after dewatering, was sent to the struvite precipitation. The different scenarios were evaluated for the LCA based on real data from the existing WWTP and modelling of different configuration changes. The modelling concludes that under the elutriation scenario around 43% of influent phosphorus (P inflow to the WWTP) could be recovered as struvite, increasing to 48% with WASSTRIP. Greenhouse effect and total costs (TAEC, per m3 wastewater treated), related to the sludge line operation, were modelled to be respectively 2% and 18% lower with struvite recovery via elutriation than without struvite recovery, whereas they were both higher with the WASSTRIP-based configuration compared to without struvite recovery.
“An integral approach to sludge handling in a WWTP operated for EBPR aiming phosphorus recovery: Simulation of alternatives, LCA and LCC Analyses”, M. Roldan et al., Water Research 175 (2020) 115647 DOI
For further information, LIFE ENRICH project website
Finland-based, global fertiliser company (and ESPP member) has launched in Finland a 100% recycled, organic granular fertiliser product, eligible for Organic Farming. BIO 8-4-2 (NPK) is recommended as a supplementary fertiliser for all crops, for spring or autumn application, including for oilseeds, cereals, grassland, potatoes … 60% of P-content is calculated as plant accessible, and soil moisture facilitates nutrient release. Yara has also announced, with Lantmännen, a pilot project to use renewable energy for mineral fertiliser production, with the aim of reducing total CO2 impact of cereals by -20%. By working with the whole food chain, the objective is to reduce climate impact whilst minimising the price impact for consumers, despite the higher cost of renewable energy. Lantmännen is an agricultural cooperative of 25 000 Swedish farmers, with 10 000 staff and operations in 20 countries, in agriculture, machinery, bioenergy and food products and brands including AXA, Bonjour, Kungsörnen, GoGreen, Gooh, FINN CRISP, Schulstad and Vaasan.
Yara BIO 8-4-2 (in Finnish)
“Lantmännen and Yara lead the way towards world’s first fossil free food chain”, 13th September 2020
The European Commission has published the final JRC “Safemanure” report (now termed REcovered Nitrogen from manURE = RENURE), proposing criteria to authorise manure-derived recycled fertilising products to be used above the 170 kgN/ha for manure-derived nitrogen fixed by the Nitrates Directive.
This is absolutely not (proposed) “End-of-Manure” criteria, in that RENURE materials will remain be subject to specific management and use constraints (additional to those applicable to mineral fertilisers) to be fixed regionally for each Nitrates Vulnerable Zone by each Member State, concerning “timing and application rates …, good agro-environmental practices …ammonium emissions on field … and emissions to air resulting from storage”. The RENURE criteria also do not give an Animal By-Product End Point. Traceability and identification of RENURE materials as manure-derived will therefore be necessary.
In addition to these specific regional use criteria, RENURE materials must have a TOC:TN ratio ≤ 3 or a mineral N:TN ratio ≥ 90%. The JRC report suggests that such materials “have a similar N leaching potential and agronomic efficiency to Haber-Bosch derived and equivalent chemical N fertilisers, when applied under good management practices”. ESPP input to the RENURE process underlined that these criteria effectively penalise organic carbon input to soil: ESPP suggested that the stability of the TOC should be taken into account. ESPP also noted that materials such as 90% raw manure spiked with 10% urea would pass the criteria, as do some raw manures and most liquid fractions of manures. At this stage, these criteria are a JRC (EU Joint Research Centre) technical proposal which must now be validated by the Member States (EU Nitrates Committee) and will then face the risk of possible legal challenges, in that some environmental or agricultural NGOs and some Member States may consider that this is an attempt to facilitate intensive livestock production and allow increased manure spreading in nutrient surplus regions by circumventing the provisions of the Nitrates Directive to limit spreading of nitrogen, art. 2(g) “excreted by livestock or a mixture of litter and waste products excreted by livestock, even in processed form"
“Technical proposals for the safe use of processed manure above the threshold established for Nitrate Vulnerable Zones by the Nitrates Directive (91/676/EEC)”, European Commission JRC, September 2020, D. Huygens et al., ISBN 978-92-76-21539-4
In March 2020, ESPP wrote to the European Commission concerning that the Safemanure approach (see above) “can make a positive contribution to nutrient recycling by facilitating local use of nutrients in certain manure or digestate fractions, under appropriate and specifically defined conditions and in line with existing legislative requirements” but underlining that this “will not resolve the current obstacle posed by the Nitrates Directive to placing on the market of high-quality fertilising products derived partly or completely from manure”.
ESPP suggested that, independently of Safemanure, the European Commission should develop criteria under which nitrogen chemicals extracted from manure, which no longer contain organic carbon, should no longer be considered manure “in a processed form” (art. 2(g)). ESPP suggested that organic carbon content <1% and conformity to Fertilising Products Regulation criteria for ‘Mineral Fertiliser’ would be appropriate to ensure that chemical properties are same as synthetic mineral N fertilisers (and so e.g. leaching risk). Also, biological and contaminant safety should be ensured.
ESPP letter to European Commission requesting action on mineral fertilisers recovered from manure, 10th March 2020 http://www.phosphorusplatform.eu/regulatory
ESPP submitted input to the EU public consultation The European Commission (closed 8th September 2020, see eNews n°46) , on revision of the EU Urban Waste Water Treatment Directive (UWWTD 1991/271). The UWWTD is recognised has having been effective in reducing pollution and in improving water quality. ESPP welcomes the proposed objectives of coherence with the Circular Economy (nutrient recycling) and “extended producer responsibility” for emerging contaminants of concern in sewage (industrial chemicals, pharmaceuticals, micro-plastics) which can be an obstacle to sewage sludge valorisation and nutrient recycling. ESPP underlined in particular the problem of perfluorinated chemicals (PFAS, PFOA). ESPP also welcomed that eutrophication is identified as a key issue needing to be addressed, in particular with storm overflows, small agglomerations < 2000 p.e. and septic tanks.
EU public consultation on the Urban Waste Water Treatment Directive” (closed 8th September 2020) and ESPP input submitted HERE.
A new study estimates that (based on 2015 situation) algal blooms in Lake Erie (USA and Canada) cost some 272 million US$/year, mainly from recreation and inherent value placed on the lake by residents living < 100km from its shores (115 M€), tourism economic losses (110 M$) and loss of property value (36 M$). Accounted over 30 years, this means a total cost of over 5.3 billion US $). Actions to reduce nutrient losses, including reducing and improving fertiliser application, agricultural buffer measures, artificial wetlands, stormwater management and improvement of sewage treatment plants is estimated at 1.3 billion US$, whereas such actions are estimated to reduce algal bloom costs by 2.8 bn$ (over 30 years), so are considered cost-effective. There are few estimates of how much nutrient losses to surface waters cost to the economy and to society. Three are cited: Dodds 2007 (see SCOPE Newsletter n°72): eutrophication costs for the USA 1.5 – 4.8 bn$; Hoagland & Scatasta 2006 algal bloom costs (only) USA 82 m$ and EU 813 m$; Steffensen 2008 management of algal blooms (only) Australia 180 – 240 mAus$.
“Estimating the economic costs of algal blooms in the Canadian Lake Erie Basin”, R. Smith et al., Harmful Algae 87 (2019) 101624 https://doi.org/10.1016/j.hal.2019.101624
A discussion paper suggests that detergent phosphate bans in the USA will have only limited impact in reducing overall nutrient loads to surface waters. 95% of phosphate use in the USA is estimated to be in agriculture. Detergent P bans will not reduce inputs to surface waters where sewage passes through treatment works with binding P discharge consents, because operators will optimise to continue to discharge P to the specified limit, irrespective of changes in works inflow P load. In Minnesota, this was estimated to reduce the effectiveness of a detergent phosphate ban by 24 – 59%, and maybe by 80% in nutrient sensitive waters where most sewage treatment works are strictly consented. Local regulations, such as county-wide lawn P fertiliser bans, may show reduced effectiveness as consumers bypass the ban by purchasing online or in nearby regions: 40% of detergent purchases were estimated be coming from outside the county when Spokane had a local dishwasher P ban. The authors argue for a wide approach to policy addressing all sources of phosphorus.
“The Effectiveness of Phosphate Bans in the United States”, D. Kaiser, Review of Environmental Economics and Policy, volume 14, issue 2, Summer 2020, pp. 331–338 DOI
The launch webinar of the island of Ireland (Ireland and Northern Ireland) Nutrient Platform registered nearly 100 participants, 3rd September. Vincent O’Flaherty, NUI Galway, explained that a three-year programme had been funded by the EPA, to assess the feasibility of such a platform and then to prepare its establishment. A meeting a year ago, with 26 participating organisations, agreed objectives and terms of governance. Key objectives are to enable networking, to facilitate business opportunities in recycling and nutrient management, and dialogue with regulators and policy makers. Philip Cosgrave, Yara, presented the company’s commitment ongoing improvement of fertiliser sustainability, from production through packaging to use on the farm, in particular with advice to farmers. Yara is also actively developing recycling, including via the Nutrient Upcycling Alliance (see ESPP eNews n°41), for example with the launch in Finland of a fertiliser including recycled organic phosphorus (see above). Patrick Barrett, Department of Agriculture, Food and the Marine, outlined national bioeconomy policy development and funding opportunities in Ireland and at the EU level for circular bioeconomy activities, and noted the potential of the new Platform to help develop and scale-up business opportunities and value-chains and inform bioeconomy policy implementation. Ian Marshall led a final panel, including ESPP, which discussed the interest of developing a nutrient balance for the whole island of Ireland, the challenges and opportunities for nutrient management from EU policies: fertiliser use commitments and the Integrated Nutrient Management Action Plan in the Green Deal, achievement of Water Framework Directive objectives with climate change, the new Common Agricultural Policy and the FAST (Farm Sustainability) Tool for Nutrients, Eu R&D funding possibilities … The important role of nutrient platforms in facilitating dialogue and consensus between different industries and stakeholders was underlined.
https://nutrientsustainability.ie/
The addition of phytase enzyme to pig feed to improve uptake of phosphorus is today standard procedure in most pig production. A significant part of phosphate in grains and seeds is in ‘phytate’, the plant’s natural phosphorus storage molecule, which is not digestible for non-ruminants (pigs, chickens, humans). By breaking down phytate, phytase enables pigs to take up this protein, so reducing P-loss to manure and reducing the need to add mineral feed phosphates (e.g. calcium phosphates). Recent trials suggest however that standard agronomic recommendations may overestimate the benefits of phytase. 72 pigs were fed diets with different levels of added phytase for 25 days, with either a diet with adequate P for optimal growth, or a P-deficient diet. Phytase improved P digestibility by nearly 50% in the P-deficient diet, but only by 12% in the optimal diet. The authors note that P-release curves for phytase are based on research using P-deficient diets, in order to obtain clear results, so that current diet recommendations may be overestimating the effects of phytate use on pig P uptake, and so resulting in feed supplying below optimal P levels. In both diets, phytase slightly improved digestibility of dry matter, gross energy and crude protein.
“Does phytase release less phosphorus than we think?”, K. Olsen & J. Patience, Iowa Pork Industry Centre, Iowa State University, 7th July 2020 https://www.nationalhogfarmer.com/nutrition/does-phytase-release-less-phosphorus-we-think
Research or review papers are invited for a special issue of the journal Agronomy on sustainable use of phosphorus in agriculture: N and P in manure and crop requirements, soil-crop systems, from feed through livestock to manure nutrient mass balances and efficiencies, runoff and erosion, policies and governance, economics, ecotechnologies.
Submission deadline is 31st March 2021.
Agronomy Journal special issue submission form
A study analysed phosphorus flows through the Brussels Capital Region, Belgium (1.2 million people, 160 km2, of which <1% agriculture). Currently wastewater is treated at two sewage works, most food waste is incinerated with municipal refuse, and green waste is collected and composted. P inputs in the food system are estimated from food consumed by population, visitors, and commuters (based on Belgium national Food Consumption Survey data) plus food waste generated in consumption and trade. P in pet food, detergents and green waste is also estimated. The data suggests an average per capita dietary intake of 1.2 gP/day. The study concludes that main annual inflows are (approximately) 700 tP/y in food products, 100 tP/y in detergents, 100 tP/y in pet food and 100 tP/y in wastewater from outside the region treated at one of the sewage works. The main outflows are (approximately) 560 tP/y in treated sewage sludge, 140 tP/y in sewage works discharge and 160 tP/y (mainly from food waste) in municipal refuse incineration ash. Currently, the sewage sludge is either wet air oxidised, dried, then used as cover material in landfills, or incinerated in Belgium and Germany. The principal opportunities for P recycling are from sewage sludge, and secondly from food waste when separate collection will be scaled up. P losses from the sewage works to surface waters (currently 16% of inflow P) should be reduced with ongoing upgrades to the two works. Separate collection and anaerobic digestion of food waste within the city would increase the amount of electricity generated; P-recovery from sewage sludge does not affect the energy balance, because energy from sludge digestion is already valorised within the sewage works. The authors conclude that the potentially recyclable phosphorus could cover the fertiliser needs of the two neighbouring Brabant provinces, but only if the regulatory framework and social acceptance of such recycling are improved.
“Phosphorus and energy flows through the food system of Brussels Capital Region”, A. Papangelou, W. Achten & E. Mathijs, Resources, Conservation & Recycling 156 (2020) 104687, DOI
As part of the LIFE ENRICH project, a Life Cycle Analysis study compares two scenarios for struvite recovery before anaerobic digestion in a sewage works operating biological phosphorus removal (EBPR) in the Murcia-Este WWTP, Spain. In the first scenario WAS (waste active sludge) is thickened using dissolved air flotation and fermented during 24 h to maximize poly-P release then elutriated in gravity thickeners with primary sludge. Struvite recovery from the overflow was modelled, considering different thickening and mixing rates. In a second scenario, WASSTRIP-based phosphorus release was modelled: primary sludge was fermented to generate volatile fatty acids then mixed with WAS in anaerobic P-release tanks and the resulting soluble-P enriched solution, after dewatering, was sent to the struvite precipitation. The different scenarios were evaluated for the LCA based on real data from the existing WWTP and modelling of different configuration changes. The modelling concludes that under the elutriation scenario around 43% of influent phosphorus (P inflow to the WWTP) could be recovered as struvite, increasing to 48% with WASSTRIP. Greenhouse effect and total costs (TAEC, per m3 wastewater treated), related to the sludge line operation, were modelled to be respectively 2% and 18% lower with struvite recovery via elutriation than without struvite recovery, whereas they were both higher with the WASSTRIP-based configuration compared to without struvite recovery.
“An integral approach to sludge handling in a WWTP operated for EBPR aiming phosphorus recovery: Simulation of alternatives, LCA and LCC Analyses”, M. Roldan et al., Water Research 175 (2020) 115647 DOI
For further information, LIFE ENRICH project website
Seven LCA studies of phosphorus recycling as struvite from wastewater are summarised, plus six of struvite from urine, dating from 2012 to 2018 (not including the paper above). The authors note considerable variation both in the LCA methodology and in the boundaries considered. Most of the LCAs include some “offset” for the environmental impacts of producing conventional fertilisers replaced by struvite, but some consider both N and P and some either only N or only P. Some of the LCAs include a sludge or nutrient management credit. Other aspects also vary considerably, with some of the LCAs, but not all, considering infrastructure, some considering that struvite might increase eutrophication (based on nutrient content of struvite applied as fertiliser), others that struvite reduces eutrophication (calculating the struvite nutrient content as removed from sewage works discharge), some but not all considering electricity consumption, etc. Furthermore, only two of the studies used data from full-scale struvite recovery installations, the others relying on literature or pilot plants. The authors suggest that that the most reliable (of the 13 studies assessed) is likely Remy & Jossa 2015 (P-REX deliverable 9.2, see summary in SCOPE Newsletter n°115), which is based on data from full scale and pilot plants, includes fertiliser offsets and infrastructure, and considers a range of impact categories. This P-REX LCA concluded that struvite precipitation has net beneficial impacts on greenhouse emissions, and eutrophication and (for configurations with precipitation downstream of sludge dewatering) on human and environmental toxicity.
“Life cycle assessment review of struvite precipitation in wastewater treatment”, M. Sena, A. Hicks, Resources, Conservation & Recycling 139 (2018) 194–204 DOI
“Sustainable sewage sludge management fostering phosphorus recovery and energy efficiency”, P-REX deliverable 9.2 report, C. Remy & P. Jossa, 2015, 86 pages HERE
Two recent publications add to existing data confirming that struvite (magnesium ammonium phosphate, a form of phosphate in which phosphorus is recovered from wastewaters) is safe and non-toxic.
Shim, Won et al.. (2019) tested the oral toxicity of struvite on rats. The struvite was precipitated from pig manure centrate in a 20 litre lab reactor, then pre-treated by microwave irradiation or heat sterilisation (550°C x 30 mins). 30 rats were fed, for 28 days, 1 or 10 mg/kg body weight/day either one of the two pre-treated struvites or no struvite (P levels as in standard rat diet). Rats were then sacrificed, body weight and blood metabolites measured and histopathological examinations carried out on liver, kidney, lung and heart. No significant differences were found in the struvite-fed rats and no abnormalities. The authors conclude no oral toxicity of struvite over 28 days at these doses. Based on solubility tests, they suggest that such pre-treated struvite could replace currently-used feed phosphates in livestock diets.
Kim et al. (2019, partly the same authors as Shim et al. above) tested the same pre-treated struvite in broiler chicken diet (204 chickens, inc. controls) for 28 days. Growth showed to be the same as with standard feed phosphate (dicalcium phosphate). No significant differences were found in histopathological examination of key organs: heart, kidney, liver, gizzard, intestines, tibia. The authors again conclude no oral toxicity under these conditions and at the dose of agronomic diet P levels, and possibility to use pre-treated struvite as a poultry feed P-additive.
NOTE: ESPP reports these studies because they add to other evidence of the toxicological safety of struvite, which is relevant for its handling etc. when used as a fertiliser or in industry. ESPP does not recommend using struvite recovered from wastewater or manure in animal feed, for reasons of public confidence. This might also be illegal in Europe because the Animal By-Products Regulations prohibit use of “faeces, urine … (or) … waste obtained from wastewaters …irrespective of processing”
“In Vivo Toxicity and In Vitro Solubility Assessment of Pre-Treated Struvite as a Potential Alternative Phosphorus Source in Animal Feed”, S. Shim et al., Animals 2019, 9, 78, DOI:10.3390/ani9100785
“Evaluation of Struvite Recovered from Swine Wastewater as an Alternative Phosphorus Source in Broiler Feed”, M. Kim et al., Agriculture 2019, 9, 221, DOI:10.3390/agriculture9100221
See also: .“Design and optimization of fluidized bed reactor operating conditions for struvite recovery process from swine wastewater”, S. Shim, S. Won, et al., 2020, Processes, 8, 422 – 438 DOI: 10.3390/pr8040422 (Open Access)
See also: “Simultaneous Removal of Pollutants and Recovery of Nutrients from High-Strength Swine Wastewater Using a Novel Integrated Treatment Process”, S. Shim, S. Won et al., Animals 2020, 10, 835; DOI: 10.3390/ani10050835
S. Shim, A. Reza, S. Kim, N. Ahmed, S. Won, and C. Ra. 2020. “Simultaneous removal of pollutants and recovery of nutrients from high-strength swine wastewater using a novel integrated treatment process”, animals, 10, 835 – 853.
Tests with 384 piglets and modelling suggest that use of a highly water soluble phosphate feed additive significantly improves whole-system PUE (phosphorus use efficiency), increases pig weight gain and reduces manure phosphorus, compared to use of a less water soluble phosphate. The 35-day pig trials used four different diet levels (0.05% to 0.2%) of water soluble MDCP mono-dicalcium phosphate and standard feed phosphate DCP dicalcium phosphate. Whole-system takes into account manure application to soil, feed crop production (soy, maize), fertiliser use, soil P accumulation and so phosphate rock consumption. The fertiliser value of manure from the piglets on different feeds was assessed by pot trials using lettuce, because manure is often recycled for vegetable production in China. Conclusions are that, for example, for 1 kg meat production, 0.1% water soluble phosphate feed additive improves whole system PUE by 18% compared to 0.2% DCP.
“A higher water-soluble phosphorus supplement in pig diet improves the whole system phosphorus use efficiency”, L. Liu et al., J. Cleaner Production 272 (2020) 122586 DOI
A review from China presents data and summarises opportunities for use of microalgae to remove nutrients from anaerobic digester effluents, with data mainly from pig manure digestate. Microalgae production can be used for extraction of lipids, biofuel production, as biomass to feed back into the digestor and increase methane production, or as an organic fertiliser and soil amendment. Microalgae have shown to tolerate high organic compound concentrations in digestates, and to be able to remove 30 – 96% of COD, 20 – 95% of ammonia-N and 20 – 98% of phosphorus, depending on conditions. Although microalgae prefer to metabolise ammonium nitrogen (rather than nitrate), high ammonium levels can be toxic to microalgae (> 120 mg/l). Another challenge is turbidity, limiting light and so microalgae photosynthesis. One simple solution to this is to dilute the digestate, but this poses logistic problems.
“Nutrients removal and biomass production from anaerobic digested effluent by microalgae: A review”, G. Li et al., Int J Agric & Biol Eng, 2019; 12(5): 8–13, DOI Open Access.
The BONUS RETURN project final conference (webinar 8 September 2020), attended by ca. 50 stakeholders, presented conclusions and recommendations on how ecotechnologies can turn nutrients and carbon from environmental problems into circular solutions in the Baltic Sea Region. The program was moderated by Arno Rosemarin (SEI). In the first session, the coordinator Karina Barquet (SEI) welcomed the audience and gave a short introduction to the program. Biljana Macura followed with a review of ecotechnologies for circulating nutrients and carbon in the Baltic Sea Region. Erik Kärrman (RISE) and Soren Marcus Pedersen (UCPH) presented a sustainability analysis of the three catchment areas selected as target regions for the program – river basins of 1,000-2,000 km² draining to the Baltic Sea – Fyrisån River (Uppland, Sweden), Vantaanjoki River (Helsinki Metropolitan Area, Finland) and Slupia River (Slupsk, Poland), offering to study pressures from agricultural and forest activities as well as from large, densely populated agglomerations. Jari Koskiaho (SYKE) and Tomasz Okruszko (WULS) presented the SWAT modelling results of the impact of ecotechnologies on nutrient levels in the three river basins. After the coffee break Sten Stenbeck (RISE) introduced the circular innovations that were pilot-tested during the project, referring to three selected emerging ecotechnologies for nutrient and carbon reuse (see below). After a review of barriers and opportunities for closing the loop in the Baltic Sea Region presented by Linn Järnberg and Nelson Ekane (both SEI), Mark Rasmussen, Olle Olson (both SEI), Marek Gielczewski (WULS) and Jari Koskiaho (SYKE) gave an overview of project related success stories. The use of phosphogypsum on cropland to retain phosphorus and reduce losses, proved particularly promising for widespread application in the Baltic region, potentially preventing 2,000 annual tons of phosphorus inflows to the Baltic Sea if implemented over large areas in a number of the riparian countries (see ESPP eNews n°36). After altogether ten years of testing, this practice can now be recommended for extensive application, using low-contaminant phosphogypsum (a by-product from processing of igneous phosphate rock), or natural gypsum where available, without worries for soil health and water quality. Finally, Steven Bachelder (Uppsala University) showed an amusing learning game before Karina Barquet (SEI) summarized and closed the session with recommendations for future policy and research
BONUS RETURN project, 2017-2020: a joint program of 6 science partners from Denmark (University of Copenhagen), Finland (SYKE) and Poland (Warsaw University of Life Sciences), Sweden (Stockholm Environment Institute, Research Institutes of Sweden, Uppsala University), coordinated by the Stockholm Environment Institute.
Recording of 8th September 2020 webinar.
The BONUS RETURN project (see above) has published final reports on ecotechnologies for nutrient management in river basins and for nutrient and carbon reuse. The report on river basin management compared impacts of source separation of black water (toilet) and grey water (other household wastewater), nutrient removal in municipal wastewater and agricultural nutrient Best Management Practices (BMPs, including constructed wetlands). This concluded, in the catchments studied, that agricultural BMPs could reduce nutrient loads (N and P) by 30-40%, compared to 4-12% for actions addressing municipal wastewaters, or <1% by increasing agricultural soil carbon content. The report concludes that a combination of different measures will be needed, depending on local catchment situations, to reduce nutrient inputs to the Baltic, and that other benefits must also be considered such as nutrient recycling and soil productivity improvement.
BONUS RETURN also selected and tested three promising ecotechnologies for nutrient and carbon reuse, with pilot plants set up and tested in Sweden, Finland and Poland. The selection process is described in a first report 28/6/2018 (press release 5/4/2018). An open “Challenge” was organised. Thirteen entries were received (not listed), from which four finalists and then from these three winners for pilot testing and pre-commercialisation support were selected. The three selected for testing are: BioPhree (Aquacare, NL, see ESPP eNews n°29), Ravita (HSY Helsinki) and Terranova Energy (Germany), both see ESPP’s SCOPE Newsletter n°132) and the fourth finalist was Carbonext, a technology for splitting biogas (methane) to produce a clean coke fuel and hydrogen gas.
BioPhree was tested in Knivsta Stockholm at pilot container scale. No data or results from the tests are provided at this stage.
Ravita post-precipitation recovery of iron phosphate was tested at a pilot plant at the Viikinmäki, Helsinki, municipal wastewater treatment plant (1000 p.e. scale, since 2019 see ESPP’s SCOPE Newsletter n°132). Development of recovery of phosphorus, nitrogen and iron (recycling as a coagulant) from the iron phosphate is underway.
TerraNova was tested in Gävle, Sweden. see ESPP’s SCOPE Newsletter n°132. No data or results from the tests are provided at this stage.
BONUS RETURN effective ecotechnologies in river basins Deliverable D.4.2. (29/2/2020) report and “Carbon and nutrient recycling ecotechnologies in three Baltic Sea river basins –the effectiveness in nutrient load reduction”, J. Koskiaho et al., 2020 Ecohydrology & Hydrobiology in print, DOI.
BONUS RETURN ecotechnologies for nutrient and carbon reuse: press release 5/4/2018 and Deliverable D.3.7 (28/6/2018) report