Attenuation of long waves through regions of irregular floating ice and bathymetry

TL;DR

This paper revises theoretical models for wave attenuation over irregular floating ice and bathymetry, correcting previous overestimations, and supports findings with numerical simulations and field data comparisons.

Contribution

It introduces a corrected energy-conserving model for wave attenuation over random ice and bathymetry, integrating fragmented ice effects into long wavelength wave theory.

Findings

The revised model conserves energy and predicts attenuation accurately.

Numerical simulations validate the theoretical predictions.

The model reproduces key features of field data, including frequency dependence and roll-over effect.

Abstract

Existing theoretical results for attenuation of surface waves propagating on water of random fluctuating depth are shown to over predict the rate of decay due to the way in which ensemble averaging is performed. A revised approach is presented which corrects this and is shown to conserve energy. New theoretical predictions are supported by numerical results which use averaging of simulations of wave scattering over finite sections of random bathymetry for which transfer matrix eigenvalues are used to accurately measure decay. The model of wave propagation used in this paper is derived from a linearised long wavelength assumption whereby depth averaging leads to time harmonic waves being represented as solutions to a simple ordinary differential equation. In this paper it is shown how this can be adapted to incorporate a model of a continuous covering of the surface by fragmented floating ice. Attenuation of waves through broken ice of random thickness is then analysed in a similar manner as bed variations previously and some comparisons are made with published field data for attenuation of waves in the marginal ice zones. Key features of the data are reproduced by theory including the attenuation being proportional to a power of frequency between 2 and 4 as well as capturing the "roll-over effect" at high frequencies.