Three-dimensional gravity-capillary standing waves: computation, resonance and instability
Abstract
We present a numerical study of three-dimensional gravity-capillary standing waves by using cubic and quintic truncated Hamiltonian formulations and the Craig-Sulem expansion of the Dirichlet-Neumann operator (DNO). The resulting models are treated as triply periodic boundary-value problems and solved via a spatio-temporal collocation method without executing initial-value calculations. This approach avoids the numerical stiffness associated with surface tension and numerical instabilities arising from time integration. We reduce the number of unknowns significantly by exploiting the spatio-temporal symmetries for three types of symmetric standing waves. Comparisons with existing asymptotic and numerical results illustrate excellent agreement between the models and the full potential-flow formulation. We investigate typical bifurcations and standing waves that feature square, hexagonal, and more complex flower-like patterns under the three-wave resonance. These solutions are generalisations of the classical Wilton ripples. Temporal simulations of the computed three-dimensional standing waves exhibit perfect periodicity and reveal an instability mechanism based on the reported oblique instability in two-dimensional standing waves.
Cite
@article{arxiv.2512.11191,
title = {Three-dimensional gravity-capillary standing waves: computation, resonance and instability},
author = {Xin Guan},
journal= {arXiv preprint arXiv:2512.11191},
year = {2025}
}
Comments
Delete original figure 1; correct the typos in Eqs (20)-(25), (28)-(31), (36)-(39); Rewrite Eqs (40)-(42); Replace the original wrong figure 11(b); Add references [49]-[53]