Episodic flooding causes sudden deoxygenation shocks in human-dominated rivers

Zhou, Yongqiang; Wang, Jinling; Zhou, Lei; Zhi, Wei; Zhang, Yunlin; Qin, Boqiang; Wu, Fengchang; Woolway, R. Iestyn; Jane, Stephen F.; Jeppesen, Erik; Hamilton, David P.; Xenopoulos, Marguerite A.; Spencer, Robert G. M.; Battin, Tom J.; Leavitt, Peter R.

Episodic flooding causes sudden deoxygenation shocks in human-dominated rivers

Yongqiang Zhou (), Jinling Wang, Lei Zhou, Wei Zhi, Yunlin Zhang (), Boqiang Qin, Fengchang Wu, R. Iestyn Woolway, Stephen F. Jane, Erik Jeppesen, David P. Hamilton, Marguerite A. Xenopoulos, Robert G. M. Spencer, Tom J. Battin and Peter R. Leavitt ()
Additional contact information
Yongqiang Zhou: Chinese Academy of Sciences
Jinling Wang: Chinese Academy of Sciences
Lei Zhou: Chinese Academy of Sciences
Wei Zhi: Hohai University
Yunlin Zhang: Chinese Academy of Sciences
Boqiang Qin: Chinese Academy of Sciences
Fengchang Wu: Chinese Research Academy of Environmental Sciences
R. Iestyn Woolway: Menai Bridge
Stephen F. Jane: Cornell University
Erik Jeppesen: Aarhus University
David P. Hamilton: Griffith University
Marguerite A. Xenopoulos: Peterborough
Robert G. M. Spencer: Florida State University
Tom J. Battin: École Polytechnique Fédérale de Lausanne (EPFL)
Peter R. Leavitt: University of Regina

Nature Communications, 2025, vol. 16, issue 1, 1-10

Abstract: Abstract Dissolved oxygen (DO) sustains river ecosystems, but the effects of hydrological extremes remain poorly understood. While high river discharge (Q) enhances aeration, floods also deliver oxygen-consuming pollutants, making net impacts uncertain. Here, we analyze daily DO and its percent saturation (DO%sat), and Q in 1156 Chinese rivers over three years. We show that DO and DO%sat decrease with rising Q in 69.1% and 55.7% of rivers, respectively. Floods (Q > 95th percentile) cause abrupt declines in both DO (19.7%) and DO%sat (16.2%) in 80.1% and 69.4% of the rivers, respectively, with the sharpest declines in agricultural and urban areas. These abrupt deoxygenation events link to increased ammonium and land-use intensity, causing more frequent hypoxia in developed regions. Contrary to initial expectations, floods often reduce oxygen levels, with faster recovery in urbanized regions. As climate change intensifies flooding, such sudden deoxygenation shocks may degrade aquatic ecosystems particularly in human-altered landscapes.

Date: 2025
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DOI: 10.1038/s41467-025-62236-5

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