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Submarine canyons are common features of the coastal ocean. Although they are known to be hotspots of turbulence that enhance diapycnal transport in their stratified waters, the dynamics of canyon mixing processes are poorly understood. Most studies of internal wave dynamics within canyons have focused on a handful of canyons with along‐axis slopes less steep than semidiurnal (D2) internal wave characteristics (subcritical). Here, we present the first tidally resolving observations within a canyon with a steeply sloping axis (supercritical). A process study consisting of two 24 h shipboard stations and a profiling mooring was conducted in the La Jolla Canyon off the coast of La Jolla, CA. Baroclinic energy flux is oriented up‐canyon and decreases from 182 ±18 W m−1 at the canyon mouth to
46±5 W m−1 near the head. The ratio of horizontal kinetic energy to available potential energy and the observed group speed of each mode are lower than expected for freely propagating D2 internal waves at each station, indicating partial reflection. Harmonic analysis reveals that variance is dominated by the D2 tide. Moving up‐canyon, the relative importance of D2 decreases and its higher harmonics are needed to account for a majority of the observed variance, indicating steepening. Steep internal tides cause large isopycnal displacements (∼50 m in 100 m water depth) and high strain events. These events coincide with enhanced O(
10−7−10−5 m2 s−3) dissipation of turbulent kinetic energy at mid‐depths.
As flow goes over and around topography, energy and momentum can be lost from the steady flow via bottom drag, lee waves, and generation of wake eddies (Johnston, Schönau, et al., 2019). The rough topography in the western Pacific (Figure 1) removes energy and momentum from energetic currents in both the deep ocean and the upper ocean with surface and internal tides often mediating this energy cascade to smaller scales via bottom drag, lee waves, and wake eddies (
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