Benjamin-Feir instability of Stokes waves in finite depth

Abstract

Whitham and Benjamin predicted in 1967 that small-amplitude periodic traveling Stokes waves of the 2d-gravity water waves equations are linearly unstable with respect to long-wave perturbations, if the depth h is larger than a critical threshold hWB ≈ 1.363. In this paper we completely describe, for any value of h > 0, the four eigenvalues close to zero of the linearized equations at the Stokes wave, as the Floquet exponent μ is turned on. We prove in particular the existence of a unique depth hWB, which coincides with the one predicted by Whitham and Benjamin, such that, for any 0 < h < hWB, the eigenvalues close to zero remain purely imaginary and, for any h > hWB, a pair of non-purely imaginary eigenvalues depicts a closed figure "8", parameterized by the Floquet exponent. As h hWB+ this figure "8" collapses to the origin of the complex plane. The proof combines a symplectic version of Kato's perturbative theory to compute the eigenvalues of a 4 × 4 Hamiltonian and reversible matrix, and KAM inspired transformations to block-diagonalize it. The four eigenvalues have all the same size O(μ) - unlike the infinitely deep water case in [6]- and the correct Benjamin-Feir phenomenon appears only after one non-perturbative block-diagonalization step. In addition one has to track, along the whole proof, the explicit dependence of the entries of the 4 × 4 reduced matrix with respect to the depth h.