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Modulation of extreme flood levels by impoundment significantly offset by floodplain loss downstream of the Three Gorges Dam

Modulation of extreme flood levels by impoundment significantly offset by floodplain loss downstream of the Three Gorges Dam
Modulation of extreme flood levels by impoundment significantly offset by floodplain loss downstream of the Three Gorges Dam
River flooding—the world's most significant natural hazard—is likely to increase under anthropogenic climate change. Most large rivers have been regulated by damming, but the extent to which these impoundments can mitigate extreme flooding remains uncertain. Here the catastrophic 2016 flood on the Changjiang River is first analyzed to assess the effects of both the Changjiang's reservoir cascade and the Three Gorges Dam (TGD), the world's largest hydraulic engineering project on downstream flood discharge and water levels. We show that the Changjiang's reservoir cascade impounded over 30.0 × 103 m3/s of flow at the peak of the flood on 25 July 2016, preventing the occurrence of what would otherwise have been the second largest flood ever recorded in the reach downstream of the TGD. Half of this flood water storage was retained by the TGD alone, meaning that impoundment by the TGD reduced peak water levels at the Datong hydrometric station (on 25 July) by 1.47 m, compared to pre‐TGD conditions. However, downstream morphological changes, in particular, extensive erosion of the natural floodplain, offset this reduction in water level by 0.22 m, so that the full beneficial impact of floodwater retention by the TGD was not fully realized. Our results highlight how morphological adjustments downstream of large dams may inhibit their full potential to mitigate extreme flood risk.
0094-8276
Mei, Xuefei
f09e47c8-e479-4e3a-b24d-24c87d2fb99e
Dai, Zhijun
518bc4ef-716d-461d-a781-a3e5b4d04ba7
Darby, Stephen
4c3e1c76-d404-4ff3-86f8-84e42fbb7970
Gao, Shu
79f1e4b5-0b78-4d4d-8f1f-67e9d48aaaae
Wang, Jie
377baefe-1668-4af6-80c8-1c3e1bde25db
Jiang, Weiguo
67e22c80-8ed2-494b-a6e7-19a01b3ad263
Mei, Xuefei
f09e47c8-e479-4e3a-b24d-24c87d2fb99e
Dai, Zhijun
518bc4ef-716d-461d-a781-a3e5b4d04ba7
Darby, Stephen
4c3e1c76-d404-4ff3-86f8-84e42fbb7970
Gao, Shu
79f1e4b5-0b78-4d4d-8f1f-67e9d48aaaae
Wang, Jie
377baefe-1668-4af6-80c8-1c3e1bde25db
Jiang, Weiguo
67e22c80-8ed2-494b-a6e7-19a01b3ad263

Mei, Xuefei, Dai, Zhijun, Darby, Stephen, Gao, Shu, Wang, Jie and Jiang, Weiguo (2018) Modulation of extreme flood levels by impoundment significantly offset by floodplain loss downstream of the Three Gorges Dam. Geophysical Research Letters. (doi:10.1002/2017GL076935).

Record type: Article

Abstract

River flooding—the world's most significant natural hazard—is likely to increase under anthropogenic climate change. Most large rivers have been regulated by damming, but the extent to which these impoundments can mitigate extreme flooding remains uncertain. Here the catastrophic 2016 flood on the Changjiang River is first analyzed to assess the effects of both the Changjiang's reservoir cascade and the Three Gorges Dam (TGD), the world's largest hydraulic engineering project on downstream flood discharge and water levels. We show that the Changjiang's reservoir cascade impounded over 30.0 × 103 m3/s of flow at the peak of the flood on 25 July 2016, preventing the occurrence of what would otherwise have been the second largest flood ever recorded in the reach downstream of the TGD. Half of this flood water storage was retained by the TGD alone, meaning that impoundment by the TGD reduced peak water levels at the Datong hydrometric station (on 25 July) by 1.47 m, compared to pre‐TGD conditions. However, downstream morphological changes, in particular, extensive erosion of the natural floodplain, offset this reduction in water level by 0.22 m, so that the full beneficial impact of floodwater retention by the TGD was not fully realized. Our results highlight how morphological adjustments downstream of large dams may inhibit their full potential to mitigate extreme flood risk.

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Accepted/In Press date: 21 March 2018
e-pub ahead of print date: 26 March 2018

Identifiers

Local EPrints ID: 419738
URI: http://eprints.soton.ac.uk/id/eprint/419738
DOI: doi:10.1002/2017GL076935
ISSN: 0094-8276
PURE UUID: 41db7951-7144-48bc-8cf1-9f41e91474fd
ORCID for Stephen Darby: ORCID iD orcid.org/0000-0001-8778-4394

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Date deposited: 20 Apr 2018 16:30
Last modified: 16 Mar 2024 02:59

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Author: Xuefei Mei
Author: Zhijun Dai
Author: Stephen Darby ORCID iD
Author: Shu Gao
Author: Jie Wang
Author: Weiguo Jiang

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