The University of Southampton
×
Filter your search:
University of Southampton Institutional Repository

Sustainable sediment management in reservoirs and regulated rivers: experiences from five continents

Sustainable sediment management in reservoirs and regulated rivers: experiences from five continents
Sustainable sediment management in reservoirs and regulated rivers: experiences from five continents
By trapping sediment in reservoirs, dams interrupt the continuity of sediment transport through rivers, resulting in loss of reservoir storage and reduced usable life, and depriving downstream reaches of sediments essential for channel form and aquatic habitats. With the acceleration of new dam construction globally, these impacts are increasingly widespread. There are proven techniques to pass sediment through or around reservoirs, to preserve reservoir capacity and to minimize downstream impacts, but they are not applied in many situations where they would be effective. This paper summarizes collective experience from five continents in managing reservoir sediments and mitigating downstream sediment starvation. Where geometry is favorable it is often possible to bypass sediment around the reservoir, which avoids reservoir sedimentation and supplies sediment to downstream reaches with rates and timing similar to pre-dam conditions. Sluicing (or drawdown routing) permits sediment to be transported through the reservoir rapidly to avoid sedimentation during high flows; it requires relatively large capacity outlets. Drawdown flushing involves scouring and re-suspending sediment deposited in the reservoir and transporting it downstream through low-level gates in the dam; it works best in narrow reservoirs with steep longitudinal gradients and with flow velocities maintained above the threshold to transport sediment. Turbidity currents can often be vented through the dam, with the advantage that the reservoir need not be drawn down to pass sediment. In planning dams, we recommend that these sediment management approaches be utilized where possible to sustain reservoir capacity and minimize environmental impacts of dams
sediment management, regulated rivers, reservoir sedimentation, reservoir sustainbility
256-280
Kondolf, Mathias
10f7a0a3-e1dd-4d30-826a-b1abae94d42e
Gao, Yongxuan
f64b1883-4d57-4e7d-b141-6532f615f60c
Annandale, George W.
51abf004-55a8-43a0-a3a4-2c3bb4549110
Morris, Gregory L.
b2737ba6-c559-4909-ae75-6707cf6ac951
Jiang, Enhui
dc58c06b-22b4-4482-a528-e785830b81a9
Zhang, Junhua
0e084511-6f1c-4c1b-8b1b-971a840955d6
Cao, Yongtao
1a6220dc-93ee-4828-a45e-637f7d94f8dc
Carling, Paul A.
8d252dd9-3c88-4803-81cc-c2ec4c6fa687
Fu, Kaidao
0e7ec890-3ff7-476e-afcc-43b53351f5cf
Guo, Qingchao
e8bc8d09-bd08-4db7-a823-fede4b7e0ee5
Hotchkiss, Rollin
ad1490c2-4106-476b-a0c8-454c0d8141a3
Peteuil, Christophe
eec7ea67-b28e-41b8-a98a-9c0959b689cc
Sumi, Tetsuya
8d0871a3-08b0-4ef5-9fbe-ee63b7559a0f
Wang, Hsiao-Wen
0729dcd0-7d3c-46e9-8b4e-76b657c26e97
Wang, Zhongmei
49fd8906-e877-4e04-ba63-e04b29c8e0fe
Wei, Zhilin
264937a0-0450-4e7c-93e9-afdc150afae2
Wu, Baosheng
9c5eea2e-75cd-49a4-abb5-0c8b2ca9e34b
Wu, Caiping
f4a1dc9b-75f7-44dc-a8a0-f9e65c6155c1
Yang, Chih Ted
6b2feb61-fd56-4ca2-af31-5d3b41516996
Kondolf, Mathias
10f7a0a3-e1dd-4d30-826a-b1abae94d42e
Gao, Yongxuan
f64b1883-4d57-4e7d-b141-6532f615f60c
Annandale, George W.
51abf004-55a8-43a0-a3a4-2c3bb4549110
Morris, Gregory L.
b2737ba6-c559-4909-ae75-6707cf6ac951
Jiang, Enhui
dc58c06b-22b4-4482-a528-e785830b81a9
Zhang, Junhua
0e084511-6f1c-4c1b-8b1b-971a840955d6
Cao, Yongtao
1a6220dc-93ee-4828-a45e-637f7d94f8dc
Carling, Paul A.
8d252dd9-3c88-4803-81cc-c2ec4c6fa687
Fu, Kaidao
0e7ec890-3ff7-476e-afcc-43b53351f5cf
Guo, Qingchao
e8bc8d09-bd08-4db7-a823-fede4b7e0ee5
Hotchkiss, Rollin
ad1490c2-4106-476b-a0c8-454c0d8141a3
Peteuil, Christophe
eec7ea67-b28e-41b8-a98a-9c0959b689cc
Sumi, Tetsuya
8d0871a3-08b0-4ef5-9fbe-ee63b7559a0f
Wang, Hsiao-Wen
0729dcd0-7d3c-46e9-8b4e-76b657c26e97
Wang, Zhongmei
49fd8906-e877-4e04-ba63-e04b29c8e0fe
Wei, Zhilin
264937a0-0450-4e7c-93e9-afdc150afae2
Wu, Baosheng
9c5eea2e-75cd-49a4-abb5-0c8b2ca9e34b
Wu, Caiping
f4a1dc9b-75f7-44dc-a8a0-f9e65c6155c1
Yang, Chih Ted
6b2feb61-fd56-4ca2-af31-5d3b41516996

Kondolf, Mathias, Gao, Yongxuan and Annandale, George W. et al. (2014) Sustainable sediment management in reservoirs and regulated rivers: experiences from five continents. Earth's Future, 2 (5), 256-280. (doi:10.1002/2013EF000184).

Record type: Article

Abstract

By trapping sediment in reservoirs, dams interrupt the continuity of sediment transport through rivers, resulting in loss of reservoir storage and reduced usable life, and depriving downstream reaches of sediments essential for channel form and aquatic habitats. With the acceleration of new dam construction globally, these impacts are increasingly widespread. There are proven techniques to pass sediment through or around reservoirs, to preserve reservoir capacity and to minimize downstream impacts, but they are not applied in many situations where they would be effective. This paper summarizes collective experience from five continents in managing reservoir sediments and mitigating downstream sediment starvation. Where geometry is favorable it is often possible to bypass sediment around the reservoir, which avoids reservoir sedimentation and supplies sediment to downstream reaches with rates and timing similar to pre-dam conditions. Sluicing (or drawdown routing) permits sediment to be transported through the reservoir rapidly to avoid sedimentation during high flows; it requires relatively large capacity outlets. Drawdown flushing involves scouring and re-suspending sediment deposited in the reservoir and transporting it downstream through low-level gates in the dam; it works best in narrow reservoirs with steep longitudinal gradients and with flow velocities maintained above the threshold to transport sediment. Turbidity currents can often be vented through the dam, with the advantage that the reservoir need not be drawn down to pass sediment. In planning dams, we recommend that these sediment management approaches be utilized where possible to sustain reservoir capacity and minimize environmental impacts of dams

Text
Kondolf_et_al-2014-Earth's_Future - Version of Record
Available under License Creative Commons Attribution.
Download (1MB)

More information

e-pub ahead of print date: 4 April 2014
Published date: May 2014
Keywords: sediment management, regulated rivers, reservoir sedimentation, reservoir sustainbility
Organisations: Earth Surface Dynamics

Identifiers

Local EPrints ID: 369930
URI: http://eprints.soton.ac.uk/id/eprint/369930
DOI: doi:10.1002/2013EF000184
PURE UUID: 9d1a15bd-2a51-437e-b140-e569c8fe6b11

Catalogue record

Date deposited: 14 Oct 2014 12:01
Last modified: 14 Mar 2024 18:10

Export record

Altmetrics

Contributors

Author: Mathias Kondolf
Author: Yongxuan Gao
Author: George W. Annandale
Author: Gregory L. Morris
Author: Enhui Jiang
Author: Junhua Zhang
Author: Yongtao Cao
Author: Paul A. Carling
Author: Kaidao Fu
Author: Qingchao Guo
Author: Rollin Hotchkiss
Author: Christophe Peteuil
Author: Tetsuya Sumi
Author: Hsiao-Wen Wang
Author: Zhongmei Wang
Author: Zhilin Wei
Author: Baosheng Wu
Author: Caiping Wu
Author: Chih Ted Yang

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Library staff additional information
Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×