Annual winter water level drawdowns limit shallow‐water mussel densities in small lakes

Carmignani, Jason R.; Roy, Allison H.; Hazelton, Peter D.; Giard, Holly

doi:10.1111/fwb.13324

Cited by 3 publications

(5 citation statements)

References 43 publications

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“…However, even relatively small WD magnitudes can have substantial ecological impacts. For example, within a subset of the current study lakes, Carmignani et al (2019) found WD regimes with <1 m magnitudes limited freshwater mussel distributions deeper than stable phase water levels, presumably due to their low mobility and susceptibility to desiccation. Also, short pulses of large and rapid water level recession as observed in our study may expose high mussel densities on shallow benthic shelves (e.g., Onota).…”

Section: Potential Drivers and Ecological Implications Of Wd Regimesmentioning

confidence: 76%

“…Galbraith et al (2015) found most mussels were stranded under 4 cm/d and 8 cm/d recession rates but with variable species-specific mortality after stranding. Given that many WD events in the current study possessed net daily recession rates >4 cm/d, increases in magnitude with similar recession rates will likely impact existing mussel assemblages, for which the distributions are already restricted by ongoing WD regimes (Carmignani et al 2019). Also, rapid recession rates may trap fish in shallow pools, leading to mortality via stranding or because of stressful overwintering conditions (Nagrodski et al 2012).…”

Section: Potential Drivers and Ecological Implications Of Wd Regimesmentioning

confidence: 88%

“…Due to differences in climate, watershed and lake hydromorphological features, and water level management goals, WD regimes in recreational lakes in the northeastern United States likely differ compared to hydroelectric lakes in north temperate and boreal zones. Consequently, ecological responses to WDs in recreational lakes may differ, requiring quantification of water level fluctuation to reliably estimate potential ecological impacts (e.g., Carmignani et al 2019). Furthermore, while most studies focus on WD magnitude, other hydrological components, such as timing, duration, water level recession and refill rates, and degree and duration of lakebed exposure, may help to better predict ecological responses Roy 2017, Hirsch et al 2017).…”

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confidence: 99%

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Hydrology of annual winter water level drawdown regimes in recreational lakes of Massachusetts, United States

Carmignani

Roy

Stolarski

et al. 2021

Lake and Reservoir Management

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Annual winter water level drawdown (WD) is a common lake management strategy to maintain recreational value by controlling nuisance macrophytes and preventing ice damage to shoreline infrastructure in lakes of the northeastern United States. The state of Massachusetts provides general guidelines for lake managers to implement and practice WDs. However, WD management reporting is not required and as such empirical water level records are scarce, making it difficult to assess guideline adherence and link these management actions to littoral habitat conditions. We monitored water levels bihourly in 18 lakes with ongoing WD regimes and 3 non-drawdown lakes over 3-4 yr. Our results show an interlake drawdown magnitude gradient of 0.07-2.66 m with intralake consistency across years. Corresponding WD magnitudes generated exposure of 1.3-37.6% for entire lakebeds and 9.2-71.1% for littoral zones. WD durations averaged 171 d and ranged widely from 5 to 246 d. Longer recession and refill phase durations and faster recession rates were moderately to strongly correlated with drawdown magnitudes. WDs were predominantly initiated prior to the state of Massachusetts 1 November starting guideline (83.1%) and refilled to summer reference levels after the recommended date of 1 April (70.6%). To minimize ecological impacts while still meeting recreational goals, WD performance guidelines may require a more fine-scale approach that integrates local hydrogeomorphic features and the presence of WD-sensitive littoral biotic assemblages. However, climate change model projections of warmer and wetter winters in the Northeast indicate increasing uncertainty for WD as an effective and worthwhile macrophyte control tool.

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Section: Potential Drivers and Ecological Implications Of Wd Regimesmentioning

confidence: 76%

Section: Potential Drivers and Ecological Implications Of Wd Regimesmentioning

confidence: 88%

mentioning

confidence: 99%

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Hydrology of annual winter water level drawdown regimes in recreational lakes of Massachusetts, United States

Carmignani

Roy

Stolarski

et al. 2021

Lake and Reservoir Management

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“…16 Bivalve populations are constrained by annual water level drawdowns. 17 Rapid water level changes of a reservoir perish fish species living in it while some other species increased abundance, suggesting that changing water levels serves as a new technique to control fish assemblages in reservoirs. [18][19][20] Operation purpose of dam and reservoir systems sometimes include hydropower generation and water quality management as well.…”

Section: Study Backgroundmentioning

confidence: 99%

“…In the Three Gorges Reservoir, spawning areas of carp species depend on the water level where low water level is preferred for human lives while high water levels are required to sustain fish population 16 . Bivalve populations are constrained by annual water level drawdowns 17 . Rapid water level changes of a reservoir perish fish species living in it while some other species increased abundance, suggesting that changing water levels serves as a new technique to control fish assemblages in reservoirs 18–20 .…”

Section: Introductionmentioning

confidence: 99%

Towards control of dam and reservoir systems with forward–backward stochastic differential equations driven by clustered jumps

Yoshioka

2022

Adv Control Appl

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We deal with a new maximum principle‐based stochastic control model for river management through operating a dam and reservoir system. The model is based on coupled forward–backward stochastic differential equations (FBSDEs) derived from jump‐driven streamflow dynamics and reservoir water balance. A continuous‐time branching process with immigration driven by a tempered stable subordinator efficiently describes clustered inflow streamflow dynamics. This is a completely new attempt in hydrology and control engineering. Applying a stochastic maximum principle to the dynamics based on an objective functional for designing cost‐efficient control of dam and reservoir systems leads to the FBSDEs as a system of optimality equations. The FBSDEs under a linear‐quadratic ansatz lead to a tractable model, while they are solved numerically in the other cases using a least‐squares Monte‐Carlo method. Optimal controls are found in the former, while only sub‐optimal ones are computable in the latter due to a hard state constraint. Model parameters are successfully identified from a real data of a river in Japan having a dam and reservoir system. We also show that the linear‐quadratic case can capture the real operation data of the system with underestimation of the outflow discharge. More complex cases with a realistic time horizon are analyzed numerically to investigate impacts of considering the environmental flows and seasonal operational purposes. Key challenges towards more sophisticated modeling and analysis with jump‐driven FBSDEs are discussed as well.

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Major shortfalls impairing knowledge and conservation of freshwater molluscs

et al. 2021

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Annual winter water level drawdowns limit shallow‐water mussel densities in small lakes

Cited by 3 publications

References 43 publications

Hydrology of annual winter water level drawdown regimes in recreational lakes of Massachusetts, United States

Hydrology of annual winter water level drawdown regimes in recreational lakes of Massachusetts, United States

Towards control of dam and reservoir systems with forward–backward stochastic differential equations driven by clustered jumps

Major shortfalls impairing knowledge and conservation of freshwater molluscs

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