Characteristic boundary condition for thermal lattice Boltzmann methods

We introduce a non-reflecting boundary condition for the simulation of thermal flows with the lattice Boltzmann Method (LBM). We base the derivation on the locally one-dimensional inviscid analysis, and define target macroscopic values at the boundary aiming at minimizing the effect of reflections o...

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Bibliographic Details
Published in:Computers & mathematics with applications (1987) 2024-03, Vol.157, p.195-208
Main Authors: Klass, Friedemann, Gabbana, Alessandro, Bartel, Andreas
Format: Article
Language:English
Subjects:
CFD
Characteristic boundary condition
High order lattice Boltzmann methods
Locally one-dimensional inviscid
Non-reflective boundary conditions
Thermal flows
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Summary:We introduce a non-reflecting boundary condition for the simulation of thermal flows with the lattice Boltzmann Method (LBM). We base the derivation on the locally one-dimensional inviscid analysis, and define target macroscopic values at the boundary aiming at minimizing the effect of reflections of outgoing waves on the bulk dynamics. The resulting macroscopic target values are then enforced in the LBM using a mesoscopic Dirichlet boundary condition. We present a procedure which allows to implement the boundary treatment for both single-speed and high order multi-speed LBM models, by conducting a layerwise characteristic analysis. We demonstrate the effectiveness of our approach by providing qualitative and quantitative comparison of several strategies for the implementation of a open boundary condition in standard numerical benchmarks. We show that our approach allows to achieve increasingly high accuracy by relaxing transversal and viscous terms towards prescribed target values. •Definition of a characteristic boundary condition (CBC) for the Navier-Stokes-Fourier equations.•Implementation of CBC for multi-speed lattice Boltzmann methods.•Improved stability by computing Laplacians of temperature and velocity using high order moments of the distribution.•Numerical evaluation of CBC and comparison with other artificial boundary conditions.
ISSN:0898-1221
1873-7668
DOI:10.1016/j.camwa.2023.12.033