Past anthropogenic activities offset dissolved inorganic phosphorus retention in the Mississippi River basin

Lauriane Vilmin; Alexander F. Bouwman; Arthur H.W. Beusen; Wim Joost van Hoek; José M. Mogollón

doi:10.1007/s10533-022-00973-1

Past anthropogenic activities offset dissolved inorganic phosphorus retention in the Mississippi River basin

Lauriane Vilmin^*, Alexander F. Bouwman, Arthur H.W. Beusen, Wim Joost van Hoek, José M. Mogollón

^*Corresponding author for this work

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

Abstract

The rapid acceleration of anthropogenic phosphorus (P) loadings to watersheds has fuelled massive freshwater and coastal eutrophication and completely changed the global P cycle. Within watersheds, emitted P is transported downstream towards estuaries. Reservoirs can retain a significant proportion of this P. In the long term, this accumulated P can however be re-mobilized, a process lacking in current global P budgets. Here, we include P cycling in a coupled integrated assessment-hydrology-biogeochemistry framework with 0.5 by 0.5-degree spatial resolution and an annual time resolution, and apply it to the Mississippi River basin (MRB). We show that, while reservoirs have aided in the net retention of P, they serve as dissolved inorganic P (DIP) sources due to the transformation of legacy P in sediments. The increasing DIP sourcing in the MRB has been offsetting P retention in streams, especially towards the end of the twentieth century. Due to its bioavailability, DIP is the most likely form to trigger eutrophication. Although P inputs into the MRB have decreased since the 1970s, legacy effects are delaying positive outcomes of remediation measures.

Original language	English
Pages (from-to)	157-169
Number of pages	13
Journal	Biogeochemistry
Volume	161
Issue number	2
DOIs	https://doi.org/10.1007/s10533-022-00973-1
Publication status	Published - Nov 2022

Bibliographical note

Funding Information:
This work is part of the Earth and life sciences (ALW) Open Programme 2016 project no. ALWOP.230, which is financed by the Netherlands Organisation for Scientific Research (NWO). Alexander F. Bouwman and Arthur H. W. Beusen received support from PBL Netherlands Environmental Assessment Agency through in-kind contributions to The New Delta 2014 ALW Project No. 869.15.015 and No. 869.15.014.

Publisher Copyright:
© 2022, The Author(s).

Funding

This work is part of the Earth and life sciences (ALW) Open Programme 2016 project no. ALWOP.230, which is financed by the Netherlands Organisation for Scientific Research (NWO). Alexander F. Bouwman and Arthur H. W. Beusen received support from PBL Netherlands Environmental Assessment Agency through in-kind contributions to The New Delta 2014 ALW Project No. 869.15.015 and No. 869.15.014.

Keywords

Dams
Mississippi River basin
Nutrient legacy
Nutrient retention
Phosphorus
Process-based modelling

UN SDGs

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

Access to Document

10.1007/s10533-022-00973-1Licence: CC BY

s10533-022-00973-1Final published version, 866 KBLicence: CC BY

Cite this

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title = "Past anthropogenic activities offset dissolved inorganic phosphorus retention in the Mississippi River basin",

abstract = "The rapid acceleration of anthropogenic phosphorus (P) loadings to watersheds has fuelled massive freshwater and coastal eutrophication and completely changed the global P cycle. Within watersheds, emitted P is transported downstream towards estuaries. Reservoirs can retain a significant proportion of this P. In the long term, this accumulated P can however be re-mobilized, a process lacking in current global P budgets. Here, we include P cycling in a coupled integrated assessment-hydrology-biogeochemistry framework with 0.5 by 0.5-degree spatial resolution and an annual time resolution, and apply it to the Mississippi River basin (MRB). We show that, while reservoirs have aided in the net retention of P, they serve as dissolved inorganic P (DIP) sources due to the transformation of legacy P in sediments. The increasing DIP sourcing in the MRB has been offsetting P retention in streams, especially towards the end of the twentieth century. Due to its bioavailability, DIP is the most likely form to trigger eutrophication. Although P inputs into the MRB have decreased since the 1970s, legacy effects are delaying positive outcomes of remediation measures.",

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note = "Funding Information: This work is part of the Earth and life sciences (ALW) Open Programme 2016 project no. ALWOP.230, which is financed by the Netherlands Organisation for Scientific Research (NWO). Alexander F. Bouwman and Arthur H. W. Beusen received support from PBL Netherlands Environmental Assessment Agency through in-kind contributions to The New Delta 2014 ALW Project No. 869.15.015 and No. 869.15.014. Publisher Copyright: {\textcopyright} 2022, The Author(s).",

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AU - Mogollón, José M.

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N2 - The rapid acceleration of anthropogenic phosphorus (P) loadings to watersheds has fuelled massive freshwater and coastal eutrophication and completely changed the global P cycle. Within watersheds, emitted P is transported downstream towards estuaries. Reservoirs can retain a significant proportion of this P. In the long term, this accumulated P can however be re-mobilized, a process lacking in current global P budgets. Here, we include P cycling in a coupled integrated assessment-hydrology-biogeochemistry framework with 0.5 by 0.5-degree spatial resolution and an annual time resolution, and apply it to the Mississippi River basin (MRB). We show that, while reservoirs have aided in the net retention of P, they serve as dissolved inorganic P (DIP) sources due to the transformation of legacy P in sediments. The increasing DIP sourcing in the MRB has been offsetting P retention in streams, especially towards the end of the twentieth century. Due to its bioavailability, DIP is the most likely form to trigger eutrophication. Although P inputs into the MRB have decreased since the 1970s, legacy effects are delaying positive outcomes of remediation measures.

AB - The rapid acceleration of anthropogenic phosphorus (P) loadings to watersheds has fuelled massive freshwater and coastal eutrophication and completely changed the global P cycle. Within watersheds, emitted P is transported downstream towards estuaries. Reservoirs can retain a significant proportion of this P. In the long term, this accumulated P can however be re-mobilized, a process lacking in current global P budgets. Here, we include P cycling in a coupled integrated assessment-hydrology-biogeochemistry framework with 0.5 by 0.5-degree spatial resolution and an annual time resolution, and apply it to the Mississippi River basin (MRB). We show that, while reservoirs have aided in the net retention of P, they serve as dissolved inorganic P (DIP) sources due to the transformation of legacy P in sediments. The increasing DIP sourcing in the MRB has been offsetting P retention in streams, especially towards the end of the twentieth century. Due to its bioavailability, DIP is the most likely form to trigger eutrophication. Although P inputs into the MRB have decreased since the 1970s, legacy effects are delaying positive outcomes of remediation measures.

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KW - Mississippi River basin

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Past anthropogenic activities offset dissolved inorganic phosphorus retention in the Mississippi River basin

Abstract

Bibliographical note

Funding

Keywords

UN SDGs

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