English

Decay estimates for Beam equations with potentials in dimension three

Analysis of PDEs 2024-09-17 v3

Abstract

This paper is devoted to studying time decay estimates of the solution for Beam equation (higher order type wave equation) with a potential utt+(Δ2+V)u=0, u(0,x)=f(x), ut(0,x)=g(x)u_{t t}+\big(\Delta^2+V\big)u=0, \,\ u(0, x)=f(x),\ u_{t}(0, x)=g(x) in dimension three, where VV is a real-valued and decaying potential on R3\R^3. Assume that zero is a regular point of H:=Δ2+VH:= \Delta^2+V , we first prove the following optimal time decay estimates of the solution operators \begin{equation*} \big\|\cos (t\sqrt{H})P_{ac}(H)\big\|_{L^{1} \rightarrow L^{\infty}} \lesssim|t|^{-\frac{3}{2}}\ \ \hbox{and} \ \ \Big\|\frac{\sin(t\sqrt{H})}{\sqrt{H}} P_{a c}(H)\Big\|_{L^{1} \rightarrow L^{\infty}} \lesssim|t|^{-\frac{1}{2}}. \end{equation*} Moreover, if zero is a resonance of HH, then time decay of the solution operators above also are considered. It is noticed that the first kind resonance does not effect the decay rates for the propagator operators cos(tH)\cos(t\sqrt{H}) and sin(tH)H\frac{\sin(t\sqrt{H})}{\sqrt{H}}, but their decay will be dramatically changed for the second and third resonance types.

Keywords

Cite

@article{arxiv.2307.16428,
  title  = {Decay estimates for Beam equations with potentials in dimension three},
  author = {Miao Chen and Ping Li and Avy Soffer and Xiaohua Yao},
  journal= {arXiv preprint arXiv:2307.16428},
  year   = {2024}
}

Comments

43 Pages. This is a final version. To appear in JFA,2024

R2 v1 2026-06-28T11:44:06.125Z