TY - JOUR

T1 - Mitigating Diffuse Phosphorus Transfer from Agriculture According to Cost and Efficiency

AU - Haygarth, Philip

AU - ApSimon, H

AU - Betson, M

AU - Harris, D

AU - Hodgkinson, R

AU - Withers, P.J.A

PY - 2009/9

Y1 - 2009/9

N2 - Potential options for mitigating phosphorus (P) transfer from agriculture to water in England and Wales (E&W) were collated across a range of farm systems to assess their potential effectiveness in reducing mass of P transferred and potential cost (pounds sterling [£]) to the farming industry. A simple model framework (called PEASE) incorporating a number of assumptions was used to identify 15 methods for mitigating inputs of P to agricultural systems, 19 methods for preventing mobilization of P, and six methods for controlling the transport of P to streams. The scope for largest reductions in P inputs was to grassland and horticulture. Potential reductions in P mobilization were up to 1.2 kg P ha−1. Reductions in P transfer associated with transport mitigation were larger than those associated with input and mobilization methods (up to 2.2 kg P ha−1). The largest estimated reductions were achieved by installing buffer zones and constructed wetlands, the former being very cost effective (£3–5 kg−1 P saved). Plots of cost curves helped identify where the combined and cumulative P transfer reductions were attainable; these were approximately 0.2 kg ha−1 for uplands, 0.6 kg ha−1 for outdoor pigs, 0.9 kg ha−1 for intensive dairy, and 2.2 kg ha−1 for arable examples. We concluded that established catchment-scale evidence for mitigation is sparse, especially for specific farm systems in E&W. Sensitivities and uncertainties in the approach, especially associated with expert coefficients, are noted. This approach is nonetheless considered useful for prioritizing where and how best options might be most effectively targeted for least cost but greatest benefit.

AB - Potential options for mitigating phosphorus (P) transfer from agriculture to water in England and Wales (E&W) were collated across a range of farm systems to assess their potential effectiveness in reducing mass of P transferred and potential cost (pounds sterling [£]) to the farming industry. A simple model framework (called PEASE) incorporating a number of assumptions was used to identify 15 methods for mitigating inputs of P to agricultural systems, 19 methods for preventing mobilization of P, and six methods for controlling the transport of P to streams. The scope for largest reductions in P inputs was to grassland and horticulture. Potential reductions in P mobilization were up to 1.2 kg P ha−1. Reductions in P transfer associated with transport mitigation were larger than those associated with input and mobilization methods (up to 2.2 kg P ha−1). The largest estimated reductions were achieved by installing buffer zones and constructed wetlands, the former being very cost effective (£3–5 kg−1 P saved). Plots of cost curves helped identify where the combined and cumulative P transfer reductions were attainable; these were approximately 0.2 kg ha−1 for uplands, 0.6 kg ha−1 for outdoor pigs, 0.9 kg ha−1 for intensive dairy, and 2.2 kg ha−1 for arable examples. We concluded that established catchment-scale evidence for mitigation is sparse, especially for specific farm systems in E&W. Sensitivities and uncertainties in the approach, especially associated with expert coefficients, are noted. This approach is nonetheless considered useful for prioritizing where and how best options might be most effectively targeted for least cost but greatest benefit.

U2 - 10.2134/jeq2008.0102

DO - 10.2134/jeq2008.0102

M3 - Journal article

VL - 38

SP - 2012

EP - 2022

JO - Journal of Environmental Quality

JF - Journal of Environmental Quality

SN - 0047-2425

IS - 5

ER -