A deep-water closure model for surface waves on axisymmetric swirling flows

TL;DR

This paper introduces a new two-dimensional model for surface gravity waves on deep-water, axisymmetric swirling flows that overcomes limitations of previous models by not requiring potential flow assumptions or infinite-order operators.

Contribution

The authors develop a novel 2D set of equations for surface waves on swirling flows, validated numerically, and applicable to large deformations and rapid swirl conditions.

Findings

Model validated against 3D vortex flow calculations.

Overcomes limitations of potential flow and flat surface assumptions.

Applicable to flows with large free surface deformations.

Abstract

We consider the propagation of linear gravity waves on the free surface of steady, axisymmetric flows with purely azimuthal velocity. We propose a two-dimensional set of governing equations for surface waves valid in the deep-water limit. These equations come from a closure condition at the free surface that reduces the three-dimensional Euler equations in the bulk of the fluid to a set of two-dimensional equations applied only at the free surface. Since the closure condition is not obtained rigorously, it is validated numerically through comparisons with full three-dimensional calculations for vortex flows, including for a Lamb-Oseen vortex. The model presented here overcomes three limitations of existing models, namely: it is not restricted to potential base flows; it does not assume the base flow to have a flat free surface; and it does not require the use of infinite-order differential operators (such as $\tanh(\nabla)$) in the governing equations. The model can be applied in the case of rapid swirl (large Froude number) where the base free surface is substantially deformed. Since the model contains only derivatives of finite order, it is readily amenable to standard numerical study.