Resonant and near-resonant internal wave triads for non-uniform stratifications. Part 2: Vertically bounded domain with mild-slope bathymetry
Abstract
Weakly nonlinear internal wave-wave interaction is a key mechanism that cascades energy from large to small scales, leading to ocean turbulence and mixing. Oceans typically have a non-uniform density stratification profile; moreover, submarine topography leads to a spatially varying ocean depth (h). Under these conditions and assuming mild-slope bathymetry, we employ multiple-scale analysis to derive the wave amplitude equations for triadic- and self-interactions. The waves are assumed to have a slowly (rapidly) varying amplitude (phase) in space and time. For uniform stratifications, the horizontal wavenumber (k) condition for waves (1,2,3), given by k(1,a)+k(2,b)+k(3,c)=0, is unaffected as h is varied, where (a,b,c) denote the modenumber. Moreover, the nonlinear coupling coefficients (NLC) are proportional to 1/h2, implying that triadic waves grow faster while travelling up a seamount. For non-uniform stratifications, triads that do not satisfy the condition a=b=c may not satisfy the horizontal wavenumber condition as h is varied, and unlike uniform stratification, the NLC may not decrease (increase) monotonically with increasing (decreasing) h. NLC, and hence wave growth rates for both triads and self-interactions, can also vary rapidly with h. The most unstable daughter wave combination of a triad with a mode-1 parent wave can also change for relatively small changes in h. We also investigate higher-order self-interactions in the presence of a monochromatic, small amplitude bathymetry; here the bathymetry behaves as a zero frequency wave. We derive the amplitude evolution equations and show that higher-order self-interactions might be a viable mechanism of energy cascade.
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