Role of the H theorem in lattice Boltzmann hydrodynamic simulations

TL;DR

This paper reviews how the H theorem underpins the Lattice Boltzmann method, ensuring thermodynamic consistency and stability in simulating complex fluid flows and dissipative systems.

Contribution

It provides a comprehensive survey of the H theorem's role in the development and stability of the Lattice Boltzmann method for hydrodynamic simulations.

Findings

H theorem enforces thermodynamic consistency in Lattice Boltzmann models.

The H theorem contributes to numerical stability in simulations.

The method effectively models complex dissipative systems.

Abstract

In the last decade, minimal kinetic models, and primarily the Lattice Boltmann equation, have met with significant success in the simulation of complex hydrodynamic phenomena, ranging from slow flows in grossly irregular geometries to fully developed turbulence, to flows with dynamic phase transitions. Besides their practical value as efficient computational tools for the dynamics complex systems, these minimal models may also represent a new conceptual paradigm in modern computational statistical mechanics: instead of proceeding bottom-up from the underlying microdynamic systems, these minimal kinetic models are built top-down starting from the macroscopic target equations. This procedure can provide dramatic advantages, provided the essential physics is not lost along the way. For dissipative systems, one such essential requirement is the compliance with the Second Law of thermodynamics. In this Colloquium, we present a chronological survey of the main ideas behind the Lattice Boltzmann method, with special focus on the role played by the $H$ theorem in enforcing compliance of the method with macroscopic evolutionary constraints (Second Law) as well as in serving as a numerically stable computational tool for fluid flows and other dissipative systems out of equilibrium.