Multi-vortices and lower bounds on the attractor dimensions for 2D Navier--Stokes equations

TL;DR

This paper introduces a new method using multi-vortex structures to establish lower bounds on the attractor dimensions of 2D Navier--Stokes equations, providing sharp estimates previously unavailable for certain domains.

Contribution

The authors develop a novel approach based on multi-vortex configurations, extending attractor dimension bounds to bounded domains and the whole plane, surpassing prior methods reliant on Kolmogorov flows.

Findings

Lower bounds similar to classical estimates on torus and sphere

Sharp lower bounds for the whole plane case

Method applicable to various hydrodynamic equations

Abstract

We present a principally new method, which is not based on the Kolmogorov flows, for obtaining the lower bounds for the attractors dimensions of the equations related with hydrodynamics and apply it to the classical 2D Navier--Stokes equations in a bounded domain as well as for the Navier--Stokes equations with Ekman damping in the whole plane. In the case of bounded domains, we give the lower bounds, which are similar to the well-known estimate on a torus and sphere and in the case of the whole plane our estimate is sharp. Note that no lower bounds for these two cases were known before. \par We suggest to use the so-called multi-vortex, which consists of a well-separated Vishik vortices (i.e., spectrally unstable localized in space flows constructed by M.M. Vishik), as the analogue of the Kolmogorov flows. Note also that this method reproduces the known result on the torus and that it is applicable to many other equations of hydrodynamics.