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Mixing Driven by Breaking Nonlinear Internal Waves
Author(s) -
Jones N. L.,
Ivey G. N.,
Rayson M. D.,
Kelly S. M.
Publication year - 2020
Publication title -
geophysical research letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.007
H-Index - 273
eISSN - 1944-8007
pISSN - 0094-8276
DOI - 10.1029/2020gl089591
Subject(s) - internal wave , stratification (seeds) , breaking wave , geology , wave packet , convection , shoaling and schooling , mechanics , geophysics , mixing (physics) , wave shoaling , heat flux , wave propagation , mechanical wave , atmospheric sciences , longitudinal wave , physics , heat transfer , oceanography , optics , seed dormancy , germination , botany , quantum mechanics , dormancy , biology
Non‐linear internal waves (NLIW) are important to processes such as heat transfer, nutrient replenishment and sediment transport on continental shelves. Our unique field observations of shoaling NLIW of elevation revealed a variety of different wave shapes, varying from relatively symmetric waves, to waves with either steepened leading‐ or trailing‐faces; many had evidence of trapped cores. The wave shape was related to the position of maximum density overturns and diapycnal mixing. We observed both shear (where sheared currents overcome the stabilizing effects of stratification) and convective (where the local velocity exceeds the wave propagation speed) instabilities. The elevated diapycnal mixing (>10 −3 m 2 s −1 ) and heat flux ( > 500 Wm −2 ) were predominantly local to the NLIW of elevation packets, and were transported onshore 10s kilometers with the wave packets. We demonstrate that wave steepness may be a useful bulk property for the parameterization of wave‐averaged diapycnal heat flux.