Phosphorus‐Based Variable‐Rate Pig Slurry Application Reduces Greenhouse Gas Emissions and Improves Phosphorus Plant Availability

Phosphorus‐Based Variable‐Rate Pig Slurry Application Reduces Greenhouse Gas Emissions and Improves Phosphorus Plant Availability

ABSTRACT Excessive or insufficient application of phosphorus (P) fertilisers can lead to soil P build‐up or reduced crop productivity, respectively. Variable‐rate P fertilisation offers a sustainable solution to this challenge. This study compared the efficiency of pig slurry (PgS) as a P fertiliser...

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Bibliographic Details
Main Authors: Catarina Esteves, David Fangueiro, Miguel Martins, Henrique Ribeiro
Format: Article
Language:English
Published: Wiley 2025-03-01
Series:Journal of Sustainable Agriculture and Environment
Subjects:
greenhouse gas emissions
laboratory‐scale experiments
nutrient leaching
pig slurry
soil P
variable‐rate P application
Online Access:https://doi.org/10.1002/sae2.70037
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Summary:ABSTRACT Excessive or insufficient application of phosphorus (P) fertilisers can lead to soil P build‐up or reduced crop productivity, respectively. Variable‐rate P fertilisation offers a sustainable solution to this challenge. This study compared the efficiency of pig slurry (PgS) as a P fertiliser to a mineral P fertiliser (superphosphate, SPP) by evaluating their impacts on soil P availability, greenhouse gas (GHG) emissions, and nutrient leaching in different laboratory experiments. PgS was applied at three increasing rates (R1, R2 and R3) to soils with varying P levels: very low (VL), low (L) or medium (M). A control (CTRL) without P application was included. Results showed PgS was as efficient as, or superior to, SPP in increasing soil extractable P content (1%–104%). Excessive PgS application indicated to soil P build‐up. CO2 emissions were highest with PgS (204.85 mg C kg−1 soil) compared with SPP (171.26 mg C kg−1 soil), though no significant differences in N2O and CH4 emissions were observed. GHG emissions were influenced by original soil P values, with the highest emissions in VL soil (1.36 g CO2‐eq kg−1 soil). Optimal fertilisation (R2 for L soils) minimised emissions (647.56 mg CO2‐eq kg−1 soil). Total P (TP) leaching was exacerbated in our selected sandy soils and increased with higher PgS application (11.95 mg TP kg−1 soil in R3) and higher soil P levels (8.18 mg TP kg−1 soil in soil M). Similar trends were observed for N leaching. This study highlighted PgS as a vial alternative to mineral P fertilisers and underscored the importance of site‐specific variable‐rate P application, to optimise fertiliser efficiency while minimising environmental impacts.
ISSN:2767-035X

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