We discuss an approximate model for the propagation of deep irrotational water
waves, specifically the model obtained by keeping only quadratic nonlinearities in the
water waves system under the Zakharov/Craig–Sulem formulation. We argue that the
initial-value problem associated with this system is most likely ill-posed in finite
regularity spaces, and that it explains the observation of spurious amplification of
high-wavenumber modes in numerical simulations that were reported in the literature.
This hypothesis has already been proposed by Ambrose, Bona, and Nicholls (2014)
but we identify a different instability mechanism. On the basis of this analysis, we
show that the system can be “rectified”. Indeed, by introducing appropriate
regularizing operators, we can restore the well-posedness without sacrificing other
desirable features such as a canonical Hamiltonian structure, cubic accuracy as an
asymptotic model, and efficient numerical integration. This provides a first rigorous
justification for the common practice of applying filters in high-order spectral
methods for the numerical approximation of surface gravity waves. While our
study is restricted to a quadratic model, we believe it can be generalized to
any order and paves the way towards the rigorous justification of a robust
and efficient strategy to approximate water waves with arbitrary accuracy.
Our study is supported by detailed and reproducible numerical simulations.
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