Global Opportunities to Increase Agricultural Independence Through Phosphorus Recycling

S. M. Powers; R. B. Chowdhury; G. K. MacDonald; G. S. Metson; A. H.W. Beusen; A. F. Bouwman; S. E. Hampton; B. K. Mayer; M. L. McCrackin; D. A. Vaccari

doi:10.1029/2018EF001097

Global Opportunities to Increase Agricultural Independence Through Phosphorus Recycling

S. M. Powers^*, R. B. Chowdhury, G. K. MacDonald, G. S. Metson, A. H.W. Beusen, A. F. Bouwman, S. E. Hampton, B. K. Mayer, M. L. McCrackin, D. A. Vaccari

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Food production hinges largely upon access to phosphorus (P) fertilizer. Most fertilizer P used in the global agricultural system comes from mining of nonrenewable phosphate rock deposits located within few countries. However, P contained in livestock manure or urban wastes represents a recyclable source of P. To inform development of P recycling technologies and policies, we examined subnational, national, and global spatial patterns for two intersections of land use affording high P recycling potential: (a) manure-rich cultivated areas and (b) populous cultivated areas. In turn, we examined overlap between P recycling potential and nation-level P fertilizer import dependency. Populous cultivated areas were less abundant globally than manure-rich cultivated areas, reflecting greater segregation between crops and people compared to crops and livestock, especially in the Americas. Based on a global hexagonal grid (290-km² grid cell area), disproportionately large shares of subnational “hot spots” for P recycling potential occurred in India, China, Southeast Asia, Europe, and parts of Africa. Outside of China, most of the remaining manure-rich or populous cultivated areas occurred within nations that had relatively high imports of P fertilizer (net P import:consumption ratios ≥0.4) or substantial increases in fertilizer demand between the 2000s (2002–2006) and 2010s (2010–2014). Manure-rich cultivated grid cells (those above the 75th percentiles for both manure and cropland extent) represented 12% of the global grid after excluding cropless cells. Annually, the global sum of animal manure P was at least 5 times that contained in human excreta, and among cultivated cells the ratio was frequently higher (median = 8.9). The abundance of potential P recycling hot spots within nations that have depended on fertilizer imports or experienced rising fertilizer demand could prove useful for developing local P sources and maintaining agricultural independence.

Original language	English
Pages (from-to)	370-383
Number of pages	14
Journal	Earth's Future
Volume	7
Issue number	4
DOIs	https://doi.org/10.1029/2018EF001097
Publication status	Published - Apr 2019

Funding

Work was supported by Washington State University and initiated with support by the National Socio-Environmental Synthesis Center (SESYNC) under funding received from the National Science Foundation DBI-1052875. We are grateful to Stephanie G. Labou for assistance with editing. A.?F.?B. and A.?H.?W.?B. received support from PBL Netherlands Environmental Assessment Agency through in-kind contributions to The NWO New Delta 2014 ALW projects no. 869.15.015 and 869.15.014. Data used in this study: Gridded Livestock of the World (GLW 2, https://doi.org/10.1371/journal.pone.0096084), Gridded Population of the World (GPWv4, https://doi.org/10.7927/H4HX19NJ), GlobCover 2009 (https://doi.org/10.1594/PANGAEA.787668), and FAOSTAT Fertilizers by Nutrient data set (http://www.fao.org/faostat/en/#data/RFN/metadata). Compiled data were deposited on PANGAEA, a DataONE member node.

Keywords

fertilizer
manure
phosphate
phosphorus
trade
waste

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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title = "Global Opportunities to Increase Agricultural Independence Through Phosphorus Recycling",

abstract = "Food production hinges largely upon access to phosphorus (P) fertilizer. Most fertilizer P used in the global agricultural system comes from mining of nonrenewable phosphate rock deposits located within few countries. However, P contained in livestock manure or urban wastes represents a recyclable source of P. To inform development of P recycling technologies and policies, we examined subnational, national, and global spatial patterns for two intersections of land use affording high P recycling potential: (a) manure-rich cultivated areas and (b) populous cultivated areas. In turn, we examined overlap between P recycling potential and nation-level P fertilizer import dependency. Populous cultivated areas were less abundant globally than manure-rich cultivated areas, reflecting greater segregation between crops and people compared to crops and livestock, especially in the Americas. Based on a global hexagonal grid (290-km2 grid cell area), disproportionately large shares of subnational “hot spots” for P recycling potential occurred in India, China, Southeast Asia, Europe, and parts of Africa. Outside of China, most of the remaining manure-rich or populous cultivated areas occurred within nations that had relatively high imports of P fertilizer (net P import:consumption ratios ≥0.4) or substantial increases in fertilizer demand between the 2000s (2002–2006) and 2010s (2010–2014). Manure-rich cultivated grid cells (those above the 75th percentiles for both manure and cropland extent) represented 12% of the global grid after excluding cropless cells. Annually, the global sum of animal manure P was at least 5 times that contained in human excreta, and among cultivated cells the ratio was frequently higher (median = 8.9). The abundance of potential P recycling hot spots within nations that have depended on fertilizer imports or experienced rising fertilizer demand could prove useful for developing local P sources and maintaining agricultural independence.",

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AU - Bouwman, A. F.

AU - Hampton, S. E.

AU - Mayer, B. K.

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KW - waste

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ER -

Global Opportunities to Increase Agricultural Independence Through Phosphorus Recycling

Abstract

Funding

Keywords

UN SDGs

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