Abstract
A cross-sectional non-hydrostatic model with idealized topography was used to examine the processes influencing tidal mixing in the region of sills. Initial calculations with appropriate parameters for the sill at the entrance to Loch Etive showed that the model could reproduce the main features of the observed mixing in the region. In particular, the hydraulic jump in the sill region was reproduced, as was an intense mid-water jet that was observed to separate from the lee side of the sill. Shear instabilities associated with the jet appeared to be a source of mixing within the thermocline. In addition, internal lee waves were generated on the lee side of the sill, with the observed amplification because of trapping during the flood stage. Their magnitude and hence the mixing increased with increasing Froude number (F r). In the case of vertically varying buoyancy frequency, its value near the sill top determined the F r number, with its value below influencing internal waves magnitude at depth. At high F r values particularly with strong currents, short waves and overturning occurred.
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The authors are indebted to Mrs L. Parry for typing the paper and Mr R.A. Smith for help in preparing figures.
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Davies, A.M., Xing, J. On the influence of stratification and tidal forcing upon mixing in sill regions. Ocean Dynamics 57, 431–451 (2007). https://doi.org/10.1007/s10236-007-0114-5
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DOI: https://doi.org/10.1007/s10236-007-0114-5