Internal waves pump waters in and out of a deep coastal embayment of a large lake

Flood, Bryan; Wells, Mathew G.; Dunlop, Erin S.; Young, Joelle D.

doi:10.1002/lno.11292

Cited by 18 publications

(12 citation statements)

References 65 publications

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“…10a). This increase in conductivity corresponds to an increase of 1.22 × 10 7 kg of NaCl in Kempenfelt Bay, consistent with the salt input from Barrie over the winter as some of the salts are retained in groundwater and released in summer months (Oswald et al 2019;Flood et al 2020), suggesting that most of the annual input of salt into the lake likely flows into the bay from river input. After ice-off when the water column mixed, the average conductivity increased to approximately 480 μS cm −1 , 40 μS cm −1 higher than at the start of the winter (Fig.…”

Section: Conductivity Measurementssupporting

confidence: 61%

“…A main source of salinity in Lake Simcoe is river inputs such as Lovers Creek (Winter et al 2011; Flood et al 2020) on the south side of Kempenfelt Bay (Fig. 2c).…”

Section: Study Site and Methodsmentioning

confidence: 99%

“…In winter, inferred salt concentrations from conductivity measurements could provide a useful tracer for the pathways of water that carry urban road salt from the edge of the bay (Flood et al 2020). Changes in salinity within the water column could indicate how water from the edges of the bay circulate into the deeper waters.…”

Section: Pathways Of Salt and Heat To The Bottom Of The Lakementioning

confidence: 99%

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Mixing, stratification, and plankton under lake‐ice during winter in a large lake: Implications for spring dissolved oxygen levels

Yang

Wells

et al. 2020

Limnology & Oceanography

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The mixing and stratification present under ice-covered lakes during winter can potentially influence the oxygen concentrations in the subsequent spring. During winter, plankton rely on updrafts caused by convection to remain in the photic zone and perform primary production. Thus, there is a crucial link in winter between under-ice light levels, circulation, and dissolved oxygen (DO) production. Detailed observations of temperature, oxygen, and incoming solar radiation over three winters between 2015 and 2017 suggested that plankton abundance and DO concentrations were maximal near the end of the winter before the ice melted when there was increased under-ice light and convection. DO was supersaturated by the end of the severe winter of 2015 when the ice cover duration was the longest. In comparison, DO increased but was not saturated in the warmer winters of 2016 and 2017. The spring overturn started when the water column became isothermal and continued until when the mean water column temperature first exceeded 4 C, at which time, hypolimnetic DO depletion started and continued until the fall overturn. The concentration of DO when the water column becomes stratified in spring, along with the timing of the end of spring overturn, are both important initial conditions for summer DO concentrations.

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Section: Conductivity Measurementssupporting

confidence: 61%

“…A main source of salinity in Lake Simcoe is river inputs such as Lovers Creek (Winter et al 2011; Flood et al 2020) on the south side of Kempenfelt Bay (Fig. 2c).…”

Section: Study Site and Methodsmentioning

confidence: 99%

Section: Pathways Of Salt and Heat To The Bottom Of The Lakementioning

confidence: 99%

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Mixing, stratification, and plankton under lake‐ice during winter in a large lake: Implications for spring dissolved oxygen levels

Yang

Wells

et al. 2020

Limnology & Oceanography

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“…This study shows an increasing trend in the extreme wind events and its potential impacts on the water quality (e.g., water temperature, dissolved oxygen and phosphorus) of a large lake with multiple basins. It is intriguing to suggest that the frequency of analogous wind-induced events may be increasing in other large lakes with multiple basins (e.g., basins of Lake Geneva 50 , Lake Michigan—Muskegon Lake Bay 52 , and Kempenfelt Bay of Lake Simcoe 54 ), lake-rivermouth (e.g., Lake Michigan—Pere Marquette River 55 ), or interconnected basins of reservoirs (e.g., Knewstubb and Natalkuz Lakes in Nechako Reservoir 51 ). Clearly this is a subject that warrants further study.…”

Section: Discussionmentioning

confidence: 99%

“…Interbasin exchange has been observed in lakes with multiple basins elsewhere (e.g., Lake Geneva 50 , Nechako Reservoir 51 ) as well as in the Great Lakes region (e.g., Muskegon Bay 52 , Green Bay 53 , Kempenfelt Bay 54 , Pere Marquette River 55 ) . In Lake Michigan, for example, high winds can lead to coastal upwelling into Muskegon Lake causing episodic hypoxia 52 .…”

Section: Introductionmentioning

confidence: 99%

Increases in Great Lake winds and extreme events facilitate interbasin coupling and reduce water quality in Lake Erie

Jabbari

Ackerman

Boegman

et al. 2021

Sci Rep

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Climate change affects physical and biogeochemical processes in lakes. We show significant increases in surface-water temperature (~ 0.5 °C decade−1; > 0.2% year−1) and wave power (> 1% year−1; the transport of energy by waves) associated with atmospheric phenomena (Atlantic Multidecadal Oscillation and Multivariate El Niño/Southern Oscillation) in the month of August between 1980 and 2018 in the Laurentian Great Lakes. A pattern in wave power, in response to extreme winds, was identified as a proxy to predict interbasin coupling in Lake Erie. This involved the upwelling of cold and hypoxic (dissolved oxygen < 2 mg L−1) hypolimnetic water containing high total phosphorus concentration from the seasonally stratified central basin into the normally well-mixed western basin opposite to the eastward flow. Analysis of historical records indicate that hypoxic events due to interbasin exchange have increased in the western basin over the last four decades (43% in the last 10 years) thus affecting the water quality of the one of the world’s largest freshwater sources and fisheries.

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An empirical parametrization of internal seiche amplitude including secondary effects

Bueno

Bleninger

Yao³

et al. 2020

Environ Fluid Mech

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Internal waves pump waters in and out of a deep coastal embayment of a large lake

Cited by 18 publications

References 65 publications

Mixing, stratification, and plankton under lake‐ice during winter in a large lake: Implications for spring dissolved oxygen levels

Mixing, stratification, and plankton under lake‐ice during winter in a large lake: Implications for spring dissolved oxygen levels

Increases in Great Lake winds and extreme events facilitate interbasin coupling and reduce water quality in Lake Erie

An empirical parametrization of internal seiche amplitude including secondary effects

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