Impact of groundwater nitrogen legacy on water quality

Xiaochen Liu; Arthur H. W. Beusen; Hans J.M. van Grinsven; Junjie Wang; Wim Joost van Hoek; Xiangbin Ran; José M. Mogollón; Alexander F. Bouwman

doi:10.1038/s41893-024-01369-9

Impact of groundwater nitrogen legacy on water quality

Xiaochen Liu^*, Arthur H. W. Beusen, Hans J.M. van Grinsven, Junjie Wang^*, Wim Joost van Hoek, Xiangbin Ran, José M. Mogollón, Alexander F. Bouwman

^*Corresponding author for this work

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

Abstract

The loss of agricultural nitrogen (N) is a leading cause of global eutrophication and freshwater and coastal hypoxia. Despite regulatory efforts, such as the European Union’s Nitrogen Directive, high concentrations of N persist in freshwaters. Excessive N leaching and accumulation in groundwater has created a substantial N reservoir as groundwater travel times are orders-of-magnitude slower than those of surface waters. In this study we reconstructed past and projected future N dynamics in groundwater for four major river basins, the Rhine, Mississippi, Yangtze and Pearl, showcasing different N trajectories. The Rhine and Mississippi river basins have accumulated N since the 1950s and although strategies to reduce excess agricultural N have worked well in the Rhine, groundwater legacy N persists in the Mississippi. The Yangtze and Pearl river basins entered the N accumulation phase in the 1970s and the accumulation is expected to continue until 2050. Policies to reduce N pollution from fertilizers have not halted N accumulation, highlighting the importance of accounting for the N legacy in groundwater. Restoring groundwater N storage to 1970 levels by diminishing N leaching will therefore take longer in the Yangtze and Pearl (>35 years) than in the Rhine (9 years) and Mississippi (15 years). Sustainable watershed management requires long-term strategies that address the impacts of legacy N and promote sustainable agricultural practices aligned with the Sustainable Development Goals to balance agricultural productivity with water conservation.

Original language	English
Pages (from-to)	891-900
Number of pages	10
Journal	Nature Sustainability
Volume	7
Issue number	7
DOIs	https://doi.org/10.1038/s41893-024-01369-9
Publication status	Published - 12 Jun 2024

Bibliographical note

Publisher Copyright:
© The Author(s) 2024.

Funding

X.L. and A.F.B. received funding from the World Resources Institute and UNESCO (project nos. 4500462526 and WE.461001.1-P1). X.L. received funding from the European Union's Horizon Europe research and innovation programme project NAPSEA (project no. 101060418). A.F.B. and A.H.W.B. received support from PBL Netherlands Environmental Assessment Agency through in-kind contributions to The New Delta 2014 ALW projects (project nos. 869.15.015 and 869.15.014). J.W. received funding from the Dutch Ministry of Education, Culture and Science through the Netherlands Earth System Science Center (NESSC).

Funders	Funder number
Netherlands Earth System Science Centre
World Resources Institute
Ministerie van onderwijs, cultuur en wetenschap
European Union’s Horizon Europe research and innovation programme project NAPSEA	101060418
United Nations Educational, Scientific and Cultural Organization	WE.461001.1-P1, 4500462526
Planbureau voor de Leefomgeving	869.15.015, 869.15.014

UN SDGs

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

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s41893-024-01369-9Final published version, 2.06 MBLicence: CC BY

Cite this

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title = "Impact of groundwater nitrogen legacy on water quality",

abstract = "The loss of agricultural nitrogen (N) is a leading cause of global eutrophication and freshwater and coastal hypoxia. Despite regulatory efforts, such as the European Union{\textquoteright}s Nitrogen Directive, high concentrations of N persist in freshwaters. Excessive N leaching and accumulation in groundwater has created a substantial N reservoir as groundwater travel times are orders-of-magnitude slower than those of surface waters. In this study we reconstructed past and projected future N dynamics in groundwater for four major river basins, the Rhine, Mississippi, Yangtze and Pearl, showcasing different N trajectories. The Rhine and Mississippi river basins have accumulated N since the 1950s and although strategies to reduce excess agricultural N have worked well in the Rhine, groundwater legacy N persists in the Mississippi. The Yangtze and Pearl river basins entered the N accumulation phase in the 1970s and the accumulation is expected to continue until 2050. Policies to reduce N pollution from fertilizers have not halted N accumulation, highlighting the importance of accounting for the N legacy in groundwater. Restoring groundwater N storage to 1970 levels by diminishing N leaching will therefore take longer in the Yangtze and Pearl (>35 years) than in the Rhine (9 years) and Mississippi (15 years). Sustainable watershed management requires long-term strategies that address the impacts of legacy N and promote sustainable agricultural practices aligned with the Sustainable Development Goals to balance agricultural productivity with water conservation.",

author = "Xiaochen Liu and Beusen, {Arthur H. W.} and {van Grinsven}, {Hans J.M.} and Junjie Wang and {van Hoek}, {Wim Joost} and Xiangbin Ran and Mogoll{\'o}n, {Jos{\'e} M.} and Bouwman, {Alexander F.}",

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doi = "10.1038/s41893-024-01369-9",

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AU - Beusen, Arthur H. W.

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AU - Wang, Junjie

AU - van Hoek, Wim Joost

AU - Ran, Xiangbin

AU - Mogollón, José M.

AU - Bouwman, Alexander F.

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Impact of groundwater nitrogen legacy on water quality

Abstract

Bibliographical note

Funding

UN SDGs

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