Movements of the thermocline lead to high variability in benthic mixing in the nearshore of a large lake

The thermocline of Lake Ontario is in constant motion, and as it washes back and forth along the sloping lakebed there is a striking asymmetry in near‐bed stratification and benthic turbulence between its rise and fall. Detailed field observations of the stratification and water currents from the su...

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Bibliographic Details
Published in:Water resources research 2016-04, Vol.52 (4), p.3019-3039
Main Authors: Chowdhury, Mijanur R., Wells, Mathew G., Howell, Todd
Format: Article
Language:English
Subjects:
Advection
benthic boundary layers
Biological activity
Density stratification
Falling
Fluid dynamics
Freshwater
internal Poincaré wave
Lakes
Mineral nutrients
Mussels
Nutrient cycles
Stratification
Surf zone
Temperature effects
Temperature gradients
the Great Lakes
Thermocline
thermocline oscillation
thermocline swash zone
Turbulence
turbulent mixing
Variability
Water currents
Water stratification
Water temperature
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Summary:The thermocline of Lake Ontario is in constant motion, and as it washes back and forth along the sloping lakebed there is a striking asymmetry in near‐bed stratification and benthic turbulence between its rise and fall. Detailed field observations of the stratification and water currents from the summers of 2012 and 2013 showed that the thermocline motions had large amplitudes (as high as 15 m) and a dominant period between 16 and 17.5 h, corresponding to a near‐inertial internal Poincaré wave. During the falling phase, the warmer down‐slope flow was strongly stratified with near‐bed water temperature gradients of 1°C m−1. In contrast during the rising phase of colder up‐slope flow, there was an unstable stratification in near‐bed water and large temperature overturns due to the differential advection of stratified waters, i.e., the shear‐driven convective mechanism. Using a Thorpe‐scale analysis of overturns, the inferred turbulent diffusivity during the up‐slope flow was Kz =5 × 10−4 m2 s−1. In striking contrast during the down‐slope flow, the strong stratification had lower turbulent diffusivities of Kz =10−6 m2 s−1. The near bottom region of Lake Ontario within the thermocline swash‐zone has intense biological activity and the highest concentrations of invasive dreissenid mussels. We discuss the potential biological implications of the striking variability in benthic mixing and near‐bed stratification for nutrient cycling in the Lake Ontario nearshore. Key Points: The thermocline of Lake Ontario constantly washes up and down the lakebed Both turbulence and stratification change as the thermocline rises and falls Organisms in this zone experience strong variations in temperature and fluxes
ISSN:0043-1397
1944-7973
DOI:10.1002/2015WR017725