Reducing soil phosphorus fertility brings potential long-term environmental gains: A UK analysis

Soil phosphorus (P) fertility arising from historic P inputs is a major driver of P mobilisation in agricultural runoff and increases the risk of aquatic eutrophication. To determine the environmental benefit of lowering soil P fertility, a meta-analysis of the relationship between soil test P (meas...

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Bibliographic Details
Published in:Environmental research letters 2017-05, Vol.12 (6), p.63001
Main Authors: Withers, Paul J A, Hodgkinson, Robin A, Rollett, Alison, Dyer, Chris, Dils, Rachael, Collins, Adrian L, Bilsborrow, Paul E, Bailey, Geoff, Sylvester-Bradley, Roger
Format: Article
Language:English
Subjects:
Agricultural runoff
agriculture
Agronomy
Catchments
Eutrophication
Fertilizers
land runoff
Olsen-P
Phosphorus
Regression analysis
Risk
Runoff
Soil analysis
Soil engineering
Soil fertility
Soil testing
Soils
Surface runoff
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Summary:Soil phosphorus (P) fertility arising from historic P inputs is a major driver of P mobilisation in agricultural runoff and increases the risk of aquatic eutrophication. To determine the environmental benefit of lowering soil P fertility, a meta-analysis of the relationship between soil test P (measured as Olsen-P) and P concentrations in agricultural drainflow and surface runoff in mostly UK soils was undertaken in relation to current eutrophication control targets (30-35 µg P L−1). At agronomic-optimum Olsen P (16-25 mg kg−1), concentrations of soluble reactive P (SRP), total dissolved P (TDP), total P (TP) and sediment-P (SS-P) in runoff were predicted by linear regression analysis to vary between 24 and 183 µg L−1, 38 and 315 µg L−1, 0.2 and 9.6 mg L−1, and 0.31 and 3.2 g kg−1, respectively. Concentrations of SRP and TDP in runoff were much more sensitive to changes in Olsen-P than were TP and SS-P concentrations, which confirms that separate strategies are required for mitigating the mobilisation of dissolved and particulate P forms. As the main driver of eutrophication, SRP concentrations in runoff were reduced on average by 60 µg L−1 (71%) by lowering soil Olsen-P from optimum (25 mg kg−1) to 10 mg kg−1. At Olsen-P concentrations below 12 mg kg−1, dissolved hydrolysable P (largely organic) became the dominant form of soluble P transported. We concluded that maintaining agronomic-optimum Olsen-P could still pose a eutrophication risk, and that a greater research focus on reducing critical soil test P through innovative agro-engineering of soils, crops and fertilisers would give long-term benefits in reducing the endemic eutrophication risk arising from legacy soil P. Soil P testing should become compulsory in priority catchments suffering, or sensitive to, eutrophication to ensure soil P reserves are fully accounted for as part of good fertiliser and manure management.
ISSN:1748-9326
1748-9326
DOI:10.1088/1748-9326/aa69fc