The baroclinic response to wind in a small two-basin lake

Field data and two linear layered models were used to examine the baroclinic response to wind in a small elongated two-basin lake, Amisk Lake (Alberta, Canada). For the first vertical baroclinic mode, wind-forced horizontal modes were simulated using a dynamic two-layer variable cross-section (TVC)...

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Bibliographic Details
Published in:Aquatic sciences 2013-04, Vol.75 (2), p.213-233
Main Authors: Imam, Y. E., Laval, B. E., Lawrence, G. A.
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Bathymetry
Biological and medical sciences
Biomedical and Life Sciences
Ecology
Fluid mechanics
Fresh water ecosystems
Freshwater
Freshwater & Marine Ecology
Fundamental and applied biological sciences. Psychology
General aspects
Lakes
Life Sciences
Marine & Freshwater Sciences
Mathematical models
Oceanography
Research Article
Resonance
Synecology
Thalweg
Wind
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Summary:Field data and two linear layered models were used to examine the baroclinic response to wind in a small elongated two-basin lake, Amisk Lake (Alberta, Canada). For the first vertical baroclinic mode, wind-forced horizontal modes were simulated using a dynamic two-layer variable cross-section (TVC) model. The first horizontal mode, H1, was found to dominate the exchange between the two basins of Amisk Lake. The highest velocities associated with H1 occurred in the constricted channel connecting the two basins. This high velocity led to strong damping which brought H1 in near-resonance with the diurnal wind despite a difference in periods. Along with H1, the second horizontal mode, H2, was detected at a thermistor mooring. The TVC showed that H2 resulted from the coupling between along-thalweg wind distribution and the bathymetry of Amisk Lake. The damping for H2 was found to be weaker than for H1, likely because of weaker bottom drag in the connecting channel. The evolution of vertical H1 modes were simulated using a multi-layered box model. In response to wind pulses, the first vertical mode V1H1 initially dominated over higher vertical modes causing two-layer exchange. Following the faster decay of V1H1, higher vertical modes shifted the exchange to three and more layers. Our study shows the importance of the coupling between wind stress distribution and lake bathymetry in exciting horizontal modes, reveals the effect of damping on resonance with wind, and explains the evolution of exchange associated with vertical modes.
ISSN:1015-1621
1420-9055
DOI:10.1007/s00027-012-0268-1