Tackling reservoir siltation by controlled sediment flushing: Impact on downstream fauna and related management issues

Espa, Paolo; Batalla, Ramón J.; Brignoli, Maria Laura; Crosa, Giuseppe; Gentili, Gaetano; Quadroni, Silvia

doi:10.1371/journal.pone.0218822

Cited by 41 publications

(30 citation statements)

References 69 publications

(129 reference statements)

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“…Downstream impacts to aquatic species depend on both the magnitude and duration of high sediment concentration, plus factors such as oxygen content in the released water, oxygen demand by the sediment, and the presence of contaminants. Management of drawdown rate, dilution of high concentration flow with clear water, interval between flushing events, timing to avoid spawning or other biologically sensitive periods, and post-flushing releases of clear water can all be important environmental mitigation tools [67][68][69].…”

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confidence: 99%

Classification of Management Alternatives to Combat Reservoir Sedimentation

Morris¹

2020

Water

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Sedimentation is steadily depleting reservoir capacity worldwide, threatening the reliability of water supplies, flood control, hydropower energy and other benefits that form the basis of today’s water-intensive society. The strategies available to combat reservoir sedimentation may be classed into four broad categories. Three proactive categories seek to improve the sediment balance across reservoirs by: (a) reducing sediment yield from the watershed, (b) routing sediment-laden flows around or through the storage pool, and (c) removing deposited sediment following deposition. The fourth category (d) consists of strategies that adapt to capacity loss, without addressing the sediment balance. Successful management will typically combine multiple strategies. This paper presents a comprehensive classification of both proactive and adaptive strategies, consistent with current international practice. Functional descriptions and examples are given for each strategy, and criteria are provided to differentiate between them when there is potential for ambiguity. The classification categories can be used as a checklist of strategies to consider in evaluating sediment management alternatives for new designs as well as remedial work at existing sediment-challenged reservoirs. This will also help practitioners to more clearly describe and communicate the nature of their management activities. Widespread application of both active and adaptive strategies is required to bring sedimentation under control to sustain benefits of water storage for today’s and future generations.

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confidence: 99%

Classification of Management Alternatives to Combat Reservoir Sedimentation

Morris¹

2020

Water

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“…Recovery times of about 2 years were also reported after small dam removal (Carlson et al, 2018;Tullos, Finn, & Walter, 2014) and after an uncontrolled sediment release (Doretto et al, 2019). Shorter recovery times of benthic communities were generally documented in regulated Alpine streams subjected to controlled sediment flushing operations, varying from a few months up to 1 year, and mostly depending to the persistence of riverbed alteration, to seasons, and to site specificities such as the provision of macroinvertebrates by undisturbed tributaries (Espa et al, 2019). aimed to protecting the safety of the system.…”

Section: Discussionmentioning

confidence: 99%

The year after an extraordinary sedimentation event in a regulated Alpine river: The impact on benthic macroinvertebrate communities

Salmaso

Crosa

Espa

et al. 2020

River Research & Apps

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On August 2017, a massive rock slope failure triggered an extreme sedimentation event in a regulated Alpine river. Consequently, high sediment load affected the river for about 1 month, with sediment concentration peaking up to several hundred g/L, and overall sediment yield of 0.4-0.8 Mm 3. The availability of sound pre-event data concerning benthic macroinvertebrate assemblages gave us the opportunity to assess the impact of this unusually severe sediment disturbance through before/after comparison. Within 1 month from the event, all the monitored communities displayed low density, richness and diversity, with minimum values never recorded before, particularly at the most upstream investigated reach, and where riverbed aggradation was comparatively larger. Persisting riverbed alteration was also identified as a major determinant justifying the slow recovery observed during the year after the event. Overall, the high resilience of some taxa, suited to a baseline unnatural condition, allowed the fast recolonization of the investigated river reaches. However, the recovery of other taxa, more sensitive to sediment pressure, was slow or did not occur during the monitored year.

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“…The target value for the permanent SSC immission was 1 g L −1 (as the drawdown took place in the spawning period of the brown trout), but up to 10 g L −1 was permissible in the short term, i.e., a maximum of 3 g L −1 for a period of up to 24 h, a maximum of 5 g L −1 for a period up to 6 h, and a maximum of 10 g L −1 for a period up to 2 h. Steps to reduce high SSCs were taken immediately when the guidance value was exceeded for the permanent immission. As the input into the Inn River was stopped at weekends, "recovery phases" were provided for the aquatic biota [46], which is also known from other case studies [55]. Further thresholds were set by the authorities for the dissolved oxygen concentration (permanent value above 10 mg L −1 (maximum 2 h between 10 and 6 mg L −1 ), for ammonium (permanent value below 0.3 mg L −1 , up to 0.5 mg L −1 for a maximum of 2 h) and for pH (allowed range between 6 and 9).…”

Section: Case Studymentioning

confidence: 99%

“…Within the herein presented case study, a large stretch of the Tyrolean part of the Inn River was investigated in order to assess the longitudinal effects (Figure 1). Over the last few centuries multiple hydro-morphological pressures, such as land reclamation, flood protection, establishment of infrastructure (e.g., railways and highways) as well as hydropower development have taken place along the Inn River similar to other rivers in the Alps (compare to [55,56] and 9). Within the herein presented case study, a large stretch of the Tyrolean part of the Inn River was investigated in order to assess the longitudinal effects ( Figure 1).…”

Section: Case Studymentioning

confidence: 99%

Controlled Reservoir Drawdown—Challenges for Sediment Management and Integrative Monitoring: An Austrian Case Study—Part A: Reach Scale

Hauer

Haimann

Holzapfel

et al. 2020

Water

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For Europe, a reduction of 80% of the potential storage volume due to reservoir sedimentation is predicted by 2080. Sedimentation processes trigger the decrease of the storage volume and a related restriction in hydropower production. Further, the artificial downstream flushing of deposited fines has manifold effects on the aquatic ecology, including changes in morphology and sediment quality, as well as increased turbidity and subsequent stress for aquatic species. However, it is common to lower the water surface of reservoirs for technical inspections, which is not comparable to reservoir flushing operations. The presented case study deals with such a controlled drawdown beyond the operational level of the Gepatsch reservoir (Tyrol, Austria). Based on the awareness of possible ecological consequences, an advanced set of measures and an integrative monitoring design, consisting of a detailed event-based quantification of suspended sediments, changes in the morphology, especially with respect to fine sediments, and analyses of the biological quality element fish on the reach scale along the Inn River have been developed.

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Tackling reservoir siltation by controlled sediment flushing: Impact on downstream fauna and related management issues

Cited by 41 publications

References 69 publications

Classification of Management Alternatives to Combat Reservoir Sedimentation

Classification of Management Alternatives to Combat Reservoir Sedimentation

The year after an extraordinary sedimentation event in a regulated Alpine river: The impact on benthic macroinvertebrate communities

Controlled Reservoir Drawdown—Challenges for Sediment Management and Integrative Monitoring: An Austrian Case Study—Part A: Reach Scale

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