Global well-Posedness for a higher-order Benjamin-Ono-Schrödinger system in the energy space

Abstract

We study the Cauchy problem associated with the higher-order Benjamin-Ono-Schrödinger system equation* cases ∂tr-a∂x3r-bH∂x2r =cr∂xr -d∂x(rH∂xr+H(r∂xr)) +β∂x(|q|2), x,t∈ R,\\ i∂tq-α∂x2q=-βqr , cases equation* where b,c,d,α,β are positive constants and a≠ 0 is a real constant. This system was introduced by Kairzhan, Kennedy, and Sulem in Higher-order-Benjamin-Ono-NLS-System-Sulem. We prove that this system is locally well-posed in the energy space H1(R)× H1(R). Furthermore, in the case a<0, this result extends globally for initial data (r0,q0) with sufficiently small H1× H1-norm. The proof combines compactness arguments with energy methods. To provide smooth solutions, we have to deal with the lost of the derivatives phenomenon introduced by higher-order derivatives and the Hilbert transform in the nonlinear terms when performing energy estimates. This is overcome by introducing a modified energy functional that cancels the problematic terms arising in the standard energy estimates. Once this is done, we extend the method put forward by Molinet and Pilod in HOBOinH1-Didier-Molinet to study a single higher-order Benjamin-Ono equation. Their procedure includes the use of a gauge transformation of Tao's type GWP-BO-Tao, and delicate bilinear estimates in Bourgain type spaces.