Breaking-induced energy dissipation of surface gravity waves at varying scales and co-flowing wind stresses

Abstract

Breaking-induced energy dissipation is studied for individual unsteady breaking waves using laboratory measurements of unidirectional surface gravity wave groups across a range of wave scales and wind stresses. A refined framework to estimate breaking-induced dissipation ΔEbr is proposed that accounts for background dissipation from non-breaking processes. Using this framework, we show that variations in wave scale primarily influence breaking energetics, such as fractional dissipation ΔEbr/E0 and dissipation rate εb, by modifying the breaking onset threshold. Also, co-flowing wind systematically reduces both ΔEbr/E0 and εb relative to unforced conditions, as wind-forced waves break earlier with reduced crest forward-leaning. Exploiting the crest-front steepness at incipient breaking Sfront(tb) to characterise breaking onset and local crest geometry, we formulate a scaling for εb based on this local measure. This then yields ΔEbr/E0 β*\,Sb\,(τb/Tb), where β* is crest forward leaning, Sb local steepness, and τb/Tb non-dimensional breaking duration. This scaling highlights the important roles of crest asymmetry and breaking duration in setting the breaking energy dissipation. Finally, we consider the breaking strength parameter b by assessing existing steepness-based scaling laws, and relate b to Sfront(tb), yielding an approximately linear dependence once the breaking-onset threshold is considered.