Reprint
Kinetic Theory-Based Methods in Fluid Dynamics
Edited by
March 2023
246 pages
- ISBN978-3-0365-6914-7 (Hardback)
- ISBN978-3-0365-6915-4 (PDF)
This book is a reprint of the Special Issue Kinetic Theory-Based Methods in Fluid Dynamics that was published in
Chemistry & Materials Science
Computer Science & Mathematics
Physical Sciences
Summary
Kinetic theory stems from statistical mechanics established at the mesoscopic scale. The numerical methods established on kinetic theory perform unique and important roles in almost all studies of fluid dynamics. This reprint reports the recent advances in this vibrant community. The development of kinetic theory-related numerical schemes and their applications to fluid dynamics problems are the main focus.
Format
- Hardback
License
© 2022 by the authors; CC BY-NC-ND license
Keywords
X38-like vehicle; hypersonic; aerodynamic characteristics; viscous interaction effect; rarefied effect; modelling; self-propelled particles; hydrodynamic properties; simple shear flow; immersed boundary-lattice Boltzmann method; anisotropic slip; boundary condition; DUGKS; superhydrophobic surface; oscillating wall motion; fluid mechanics; kinetic theory; rarefied gas dynamics; multicomponent flows; well-balanced schemes; free-energy model; discrete unified gas-kinetic scheme; multiphase flow; flux reconstruction; SPH method; two-phase; porous media; gas-kinetic scheme; BGK model; thermal protection system; hypersonic flow; granular gases; kinetic theory; Enskog–Fokker–Planck equation; direct simulation Monte Carlo; event-driven molecular dynamics; natural convection; nanofluid; thermal lattice Boltzmann flux solver; immersed boundary method; simplified linearized lattice Boltzmann method; immersed boundary method; computational aeroacoustics; DSMC; BGK model; gas expansion; pulsed laser evaporation; time-of-flight; rarefied gas; Nesvetay; LasInEx; discrete velocity scheme; ALE; convection melting; sinusoidal side wall temperature; lattice Boltzmann method; metal foams; latent heat storage; n/a