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Sand-mining-driven reduction in Tonle Sap Lake’s critical flood pulse

Sand-mining-driven reduction in Tonle Sap Lake’s critical flood pulse
Sand-mining-driven reduction in Tonle Sap Lake’s critical flood pulse
The Tonle Sap Lake (TSL), one of the world’s most productive lake–wetland ecosystems is sustained by an annual flood pulse that reverses Lower Mekong River flow into the lake during the monsoon and returns freshwater downstream during the dry season. Recent declines in the reverse flow have previously been attributed to climate change and upstream damming. However, here we show that between 1998 and 2018, riverbed lowering of the Mekong mainstem, driven by sand mining and upstream sediment trapping, has reduced the reverse flow by between 40 and 50% (high- to low-flow year range; 47% for medium flows). Projections to 2038, with additional riverbed lowering driven by ongoing sand mining, predict reverse flow declines of 69% (64–73%) compared with 1998. We show how these changes affect the lake’s flow regulation services across the Lower Mekong system. Specifically, the reduced TSL reverse flow increases flows to the Mekong Delta by ~26 km3 (31–23 km3) during the monsoon, heightening flood risk, while decreasing dry-season flows by ~59% (50–61%), contributing to intensified saltwater intrusion and diminished agricultural yields across the Mekong’s Delta. Our results underscore how excessive sand extraction is an existential threat to the TSL–Mekong system’s sustainability.
2398-9629
Quan, L.
bbf3ef89-8345-4715-9201-720998f8a248
Hackney, Christopher
bc99c3e8-243c-4933-9346-46c707e36e0b
Vasilopoulos, G.
a55c6b3d-c8be-4956-b498-cfdfd6bddc23
Coulthard, T.J.
e14b3c90-8e7a-478d-a12e-e784ba276e6c
Hung, Nguyen Nghia
2473441b-52b2-49fc-962d-d4e619c3e6ab
Darby, Steve
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Parsons, Daniel
254b9145-8299-4c55-98ed-d37a8cdcb782
Quan, L.
bbf3ef89-8345-4715-9201-720998f8a248
Hackney, Christopher
bc99c3e8-243c-4933-9346-46c707e36e0b
Vasilopoulos, G.
a55c6b3d-c8be-4956-b498-cfdfd6bddc23
Coulthard, T.J.
e14b3c90-8e7a-478d-a12e-e784ba276e6c
Hung, Nguyen Nghia
2473441b-52b2-49fc-962d-d4e619c3e6ab
Darby, Steve
4c3e1c76-d404-4ff3-86f8-84e42fbb7970
Parsons, Daniel
254b9145-8299-4c55-98ed-d37a8cdcb782

Quan, L., Hackney, Christopher, Vasilopoulos, G., Coulthard, T.J., Hung, Nguyen Nghia, Darby, Steve and Parsons, Daniel (2025) Sand-mining-driven reduction in Tonle Sap Lake’s critical flood pulse. Nature Sustainability. (doi:10.1038/s41893-025-01677-8).

Record type: Article

Abstract

The Tonle Sap Lake (TSL), one of the world’s most productive lake–wetland ecosystems is sustained by an annual flood pulse that reverses Lower Mekong River flow into the lake during the monsoon and returns freshwater downstream during the dry season. Recent declines in the reverse flow have previously been attributed to climate change and upstream damming. However, here we show that between 1998 and 2018, riverbed lowering of the Mekong mainstem, driven by sand mining and upstream sediment trapping, has reduced the reverse flow by between 40 and 50% (high- to low-flow year range; 47% for medium flows). Projections to 2038, with additional riverbed lowering driven by ongoing sand mining, predict reverse flow declines of 69% (64–73%) compared with 1998. We show how these changes affect the lake’s flow regulation services across the Lower Mekong system. Specifically, the reduced TSL reverse flow increases flows to the Mekong Delta by ~26 km3 (31–23 km3) during the monsoon, heightening flood risk, while decreasing dry-season flows by ~59% (50–61%), contributing to intensified saltwater intrusion and diminished agricultural yields across the Mekong’s Delta. Our results underscore how excessive sand extraction is an existential threat to the TSL–Mekong system’s sustainability.

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Accepted/In Press date: 2025
Published date: 10 November 2025
Additional Information: Publisher Copyright: © The Author(s) 2025.
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Identifiers

Local EPrints ID: 507467
URI: http://eprints.soton.ac.uk/id/eprint/507467
DOI: doi:10.1038/s41893-025-01677-8
ISSN: 2398-9629
PURE UUID: c6831b4d-3438-4d63-90a3-0361719ca86c
ORCID for Steve Darby: ORCID iD orcid.org/0000-0001-8778-4394

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Date deposited: 09 Dec 2025 17:57
Last modified: 10 Dec 2025 02:35

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Contributors

Author: L. Quan
Author: Christopher Hackney
Author: G. Vasilopoulos
Author: T.J. Coulthard
Author: Nguyen Nghia Hung
Author: Steve Darby ORCID iD
Author: Daniel Parsons

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