English

Sharp bounds on the attractor dimensions for damped wave equations

Analysis of PDEs 2024-09-30 v1

Abstract

We give the explicit estimates of order γd\gamma^{-d} (with logarithmic correction in the 1D case) for the fractal dimension of the attractor of the damped hyperbolic equation (or system) in a bounded domain ΩRd\Omega\subset \mathbb R^d, d1d\ge1 with linear damping coefficient γ>0\gamma>0. The key ingredient in the proof for d3d\ge3 is Lieb's bound for the LpL_p-norms of systems with orthonormal gradients based on the Cwikel--Lieb--Rozenblum (CLR) inequality for negative eigenvalues of the Schr\"odinder operator. The case d=1d=1 is simpler, but contains a logarithmic correction term that seems to be inevitable. The 2D case is more difficult and is strongly based on the Strichartz-type estimates for the linear equation. Lower bounds of the same order for the dimension of the attractor are also obtained for a damped hyperbolic system with nonlinearity containing a small non-gradient perturbation term, meaning that in this case our estimates are optimal for d2d\ge2 and contain a logarithmic discrepancy for d=1d=1. Estimates for the various dimensions (Hausdorff, fractal, Lyapunov) of the attractor in purely gradient case are also given. We show, in particular, that the Lyapunov dimension of a non-trivial attractor is of the order γ1\gamma^{-1} in all spatial dimensions d1d\ge1.

Keywords

Cite

@article{arxiv.2409.18801,
  title  = {Sharp bounds on the attractor dimensions for damped wave equations},
  author = {A. A. Ilyin and A. G. Kostianko and S. V. Zelik},
  journal= {arXiv preprint arXiv:2409.18801},
  year   = {2024}
}
R2 v1 2026-06-28T18:59:36.732Z