<p>Inflows of phosphorus (P) to freshwaters from the wastewater and agriculture sectors of our food systems continue to reduce aquatic biodiversity and threaten human health. A range of analytical tools were applied to investigate the contributions of these two sectors to riverine P pollution in the catchments of the Somerset Levels and Moors (SLM) region of England. A substance flow analysis of current sector P use in 2021 identified a low food system P use efficiency (48–75%) and variable P input pressures of unused P of 2.1–8.5&#xa0;kg&#xa0;ha<sup>−1</sup>&#xa0;year<sup>−1</sup> driven by livestock feed imports and a high population density. Despite recent reductions in wastewater P discharges, concentration (C) and flow (Q) analysis found both point source and diffuse source signals in the river P record. River soluble reactive P (SRP) and total P (TP) flux in a range of SLM sub-catchments ranged from 0.5–1.5 and 0.75–2.4&#xa0;kg&#xa0;ha<sup>−1</sup>&#xa0;year<sup>−1</sup>, respectively. The flux of SRP and&#xa0;TP associated with diffuse sources (calculated by CQ analysis) averaged 0.3–0.5 and 0.5–0.95&#xa0;kg&#xa0;ha<sup>−1</sup>&#xa0;year<sup>−1</sup>, respectively, and was significantly positively correlated (<i>r</i><sup>2</sup> 0.6, <i>p</i> &lt; 0.01) to the agricultural P surplus in these sub-catchments. The large intercept (0.28&#xa0;kg SRP ha<sup>−1</sup> and 0.56&#xa0;kg TP ha<sup>−1</sup>) of this relationship suggested that the historical legacy P store was the main pollution threat from agriculture. An inventory of agricultural P inputs and P outputs over the last 150&#xa0;years together with a catchment soil analysis programme confirmed a legacy of soil P accumulation amounting to an average 2 t ha<sup>−1</sup>. An analysis of the potential impact of reductions in the sector P input pressure on river P concentrations suggested that on-going and planned increases in wastewater P removal efficiency must be supplemented with a major system change towards drawdown of legacy soil P reserves to lower the P pollution threat in this nationally important region.</p>

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Phosphorus legacies and water quality in the Somerset Levels and Moors, England

  • Paul J. A. Withers,
  • Shane A. Rothwell,
  • Kirsty J. Ross,
  • Hannah J. Walling

摘要

Inflows of phosphorus (P) to freshwaters from the wastewater and agriculture sectors of our food systems continue to reduce aquatic biodiversity and threaten human health. A range of analytical tools were applied to investigate the contributions of these two sectors to riverine P pollution in the catchments of the Somerset Levels and Moors (SLM) region of England. A substance flow analysis of current sector P use in 2021 identified a low food system P use efficiency (48–75%) and variable P input pressures of unused P of 2.1–8.5 kg ha−1 year−1 driven by livestock feed imports and a high population density. Despite recent reductions in wastewater P discharges, concentration (C) and flow (Q) analysis found both point source and diffuse source signals in the river P record. River soluble reactive P (SRP) and total P (TP) flux in a range of SLM sub-catchments ranged from 0.5–1.5 and 0.75–2.4 kg ha−1 year−1, respectively. The flux of SRP and TP associated with diffuse sources (calculated by CQ analysis) averaged 0.3–0.5 and 0.5–0.95 kg ha−1 year−1, respectively, and was significantly positively correlated (r2 0.6, p < 0.01) to the agricultural P surplus in these sub-catchments. The large intercept (0.28 kg SRP ha−1 and 0.56 kg TP ha−1) of this relationship suggested that the historical legacy P store was the main pollution threat from agriculture. An inventory of agricultural P inputs and P outputs over the last 150 years together with a catchment soil analysis programme confirmed a legacy of soil P accumulation amounting to an average 2 t ha−1. An analysis of the potential impact of reductions in the sector P input pressure on river P concentrations suggested that on-going and planned increases in wastewater P removal efficiency must be supplemented with a major system change towards drawdown of legacy soil P reserves to lower the P pollution threat in this nationally important region.