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Maximizing US nitrate removal through wetland protection and restoration

Author

Listed:
  • F. Y. Cheng

    (University of Waterloo)

  • K. J. Van Meter

    (University of Illinois at Chicago)

  • D. K. Byrnes

    (University of Waterloo)

  • N. B. Basu

    (University of Waterloo
    University of Waterloo
    University of Waterloo)

Abstract

Growing populations and agricultural intensification have led to raised riverine nitrogen (N) loads, widespread oxygen depletion in coastal zones (coastal hypoxia)1 and increases in the incidence of algal blooms.Although recent work has suggested that individual wetlands have the potential to improve water quality2–9, little is known about the current magnitude of wetland N removal at the landscape scale. Here we use National Wetland Inventory data and 5-kilometre grid-scale estimates of N inputs and outputs to demonstrate that current N removal by US wetlands (about 860 ± 160 kilotonnes of nitrogen per year) is limited by a spatial disconnect between high-density wetland areas and N hotspots. Our model simulations suggest that a spatially targeted increase in US wetland area by 10 per cent (5.1 million hectares) would double wetland N removal. This increase would provide an estimated 54 per cent decrease in N loading in nitrate-affected watersheds such as the Mississippi River Basin. The costs of this increase in area would be approximately 3.3 billion US dollars annually across the USA—nearly twice the cost of wetland restoration on non-agricultural, undeveloped land—but would provide approximately 40 times more N removal. These results suggest that water quality improvements, as well as other types of ecosystem services such as flood control and fish and wildlife habitat, should be considered when creating policy regarding wetland restoration and protection.

Suggested Citation

  • F. Y. Cheng & K. J. Van Meter & D. K. Byrnes & N. B. Basu, 2020. "Maximizing US nitrate removal through wetland protection and restoration," Nature, Nature, vol. 588(7839), pages 625-630, December.
  • Handle: RePEc:nat:nature:v:588:y:2020:i:7839:d:10.1038_s41586-020-03042-5
    DOI: 10.1038/s41586-020-03042-5
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    Citations

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    Cited by:

    1. Yu Hong & Ziqi He & Ruliang Liu & Wenhua Xiang & Pifeng Lei & Xi Fang, 2024. "Artificial Cultivation of Aquatic Plants Promotes Nitrogen Transformation and the Abundance of Key Functional Genes in Agricultural Drainage Ditch Sediments in the Yellow River Irrigation Area in Chin," Land, MDPI, vol. 13(10), pages 1-29, September.
    2. repec:ags:aaea22:335440 is not listed on IDEAS
    3. Eszter Tanács & Ágnes Vári & Ákos Bede-Fazekas & András Báldi & Edina Csákvári & Anett Endrédi & Veronika Fabók & Lívia Kisné Fodor & Márton Kiss & Péter Koncz & Anikó Kovács-Hostyánszki & János Mészá, 2023. "Finding the Green Grass in the Haystack? Integrated National Assessment of Ecosystem Services and Condition in Hungary, in Support of Conservation and Planning," Sustainability, MDPI, vol. 15(11), pages 1-28, May.
    4. Konstantinos Metaxoglou & Aaron Smith, 2022. "Nutrient Pollution and US Agriculture: Causal Effects, Integrated Assessment, and Implications of Climate Change," NBER Chapters, in: American Agriculture, Water Resources, and Climate Change, pages 297-341, National Bureau of Economic Research, Inc.
    5. Matthew Heiner & Matthew J. Heaton & Benjamin Abbott & Philip White & Camille Minaudo & Rémi Dupas, 2023. "Model-Based Clustering of Trends and Cycles of Nitrate Concentrations in Rivers Across France," Journal of Agricultural, Biological and Environmental Statistics, Springer;The International Biometric Society;American Statistical Association, vol. 28(1), pages 74-98, March.
    6. Zhiwei Wan & Hongqi Wu, 2022. "Evolution of Ecological Patterns of Poyang Lake Wetland Landscape over the Last One Hundred Years Based on Historical Topographic Maps and Landsat Images," Sustainability, MDPI, vol. 14(13), pages 1-17, June.
    7. Dipesh Nepal & Prem Parajuli & Ying Ouyang & Filip To & Nuwan Wijewardane & Vivek Venishetty, 2024. "Evaluation of Wetland Area Effects on Hydrology and Water Quality at Watershed Scale," Resources, MDPI, vol. 13(8), pages 1-23, August.
    8. Brendan Carberry & Tom A. Langen & Michael R. Twiss, 2021. "Surface Water Quality Differs between Functionally Similar Restored and Natural Wetlands of the Saint Lawrence River Valley in New York," Land, MDPI, vol. 10(7), pages 1-7, June.
    9. Wang, Jingjing, 2022. "Harnessing natural attenuation to reduce CAFOs nitrate emissions: An integrated modeling approach," Ecological Economics, Elsevier, vol. 199(C).
    10. Johnson, David R. & Bahalou Horeh, Marziyeh & Liu, Jing & Zuidema, Shan & Chepeliev, Maksym & Hertel, Thomas W., 2024. "Reinvestment of Revenue from Carbon Pricing Policies to Mitigate the Severity of Gulf of Mexico Hypoxia," 2024 Annual Meeting, July 28-30, New Orleans, LA 343944, Agricultural and Applied Economics Association.
    11. Jing Liu & Laura Bowling & Christopher Kucharik & Sadia Jame & Uris Baldos & Larissa Jarvis & Navin Ramankutty & Thomas Hertel, 2022. "Multi-scale Analysis of Nitrogen Loss Mitigation in the US Corn Belt," Papers 2206.07596, arXiv.org.

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