Wave-induced drift in third-order deep-water theory

Abstract: The goal of this work is to investigate particle motions beneath unidirectional, deep-water waves up to the third-order in nonlinearity. A particular focus is on the approximation known as Stokes drift, and how it relates to the particle kinematics as computed directly from the particle trajectory mapping. The reduced Hamiltonian formulation of Zakharov and Krasitskii serves as a convenient tool to separate the effects of weak nonlinearity, in particular the appearance of bound harmonics and the mutual corrections to the wave frequencies. By numerical integration of the particle trajectory mappings we are able to compute motions and resulting drift for sea-states with one, two and several harmonics. Overall, we find the linear theory yields the largest forward drift close to the surface, followed by second and third order. At greater depth this trend reverses, with linear theory yielding the smallest forward drift. Incorporating difference harmonic terms into the classical Stokes drift formulation is found to yield improved agreement with the drift obtained from nonlinear wave theories, particularly at depth.