Logarithmic lattice models for flows with boundaries

TL;DR

This paper introduces a novel approach using logarithmic lattice models in Fourier space to efficiently simulate fluid flows with boundaries, capturing small-scale effects while reducing computational costs.

Contribution

It develops new toy models for flows with walls by incorporating boundaries into the logarithmic lattice framework, preserving key properties of the original equations.

Findings

Models retain conserved quantities and symmetries.

Simulations reach very high Reynolds numbers.

Provides insights into boundary effects in fluid flows.

Abstract

Many fundamental problems in fluid dynamics are related to the effects of solid boundaries. In general, they install sharp gradients and contribute to the developement of small-scale structures, which are computationally expensive to resolve with numerical simulations. A way to access extremely fine scales with a reduced number of degrees of freedom is to consider the equations on logarithmic lattices in Fourier space. Here we introduce new toy models for flows with walls, by showing how to add boundaries to the logarithmic lattice framework. The resulting equations retain many important properties of the original systems, such as the conserved quantities, the symmetries and the boundary effects. We apply this technique to many flows, with emphasis on the inviscid limit of the Navier-Stokes equations. For this setup, simulations reach impressively large Reynolds numbers and disclose interesting insights about the original problem.