Optimal transient growth in thin-interface internal solitary waves

TL;DR

This paper investigates the optimal transient growth of perturbations in large-amplitude internal solitary waves using linear methods, revealing localized wave packets that grow rapidly with wave speed and are relevant to laboratory observations.

Contribution

It introduces a linear optimal transient growth framework for analyzing perturbations in ISWs, incorporating direct-adjoint iterations of the Navier-Stokes equations and comparisons with WKB and Gaussian wave packets.

Findings

Optimal perturbations are localized wave packets upstream of the ISW.

Energy gain of disturbances increases rapidly with wave phase velocity.

Non-normal growth mechanisms significantly contribute to total energy gain.

Abstract

The dynamics of perturbations to large-amplitude Internal Solitary Waves (ISW) in two-layered flows with thin interfaces is analyzed by means of linear optimal transient growth methods. Optimal perturbations are computed through direct-adjoint iterations of the Navier-Stokes equations linearized around inviscid, steady ISWs obtained from the Dubreil-Jacotin-Long (DJL) equation. Optimal perturbations are found as a function of the ISW phase velocity $c$ (alternatively amplitude) for one representative stratification. These disturbances are found to be localized wave-like packets that originate just upstream of the ISW self-induced zone (for large enough $c$) of potentially unstable Richardson number, $Ri < 0.25$. They propagate through the base wave as coherent packets whose total energy gain increases rapidly with $c$. The optimal disturbances are also shown to be relevant to DJL solitary waves that have been modified by viscosity representative of laboratory experiments. The optimal disturbances are compared to the local WKB approximation for spatially growing Kelvin-Helmholtz (K-H) waves through the $Ri < 0.25$ zone. The WKB approach is able to capture properties (e.g., carrier frequency, wavenumber and energy gain) of the optimal disturbances except for an initial phase of non-normal growth due to the Orr mechanism. The non-normal growth can be a substantial portion of the total gain, especially for ISWs that are weakly unstable to K-H waves. The linear evolution of Gaussian packets of linear free waves with the same carrier frequency as the optimal disturbances is shown to result in less energy gain than found for either the optimal perturbations or the WKB approximation due to non-normal effects that cause absorption of disturbance energy into the leading face of the wave.