FLIP: A method for adaptively zoned, particle-in-cell calculations of fluid flows in two dimensions
Journal of Computational Physics
The equilibrium flux method for the calculation of flows with non-equilibrium chemical reactions
Journal of Computational Physics
Scalar and parallel optimized implementation of the direct simulation Monte Carlo method
Journal of Computational Physics
Flux-corrected transport I. SHASTA, a fluid transport algorithm that works
Journal of Computational Physics - Special issue: commenoration of the 30th anniversary
Towards the ultimate conservative difference scheme V. A second-order sequel to Godunov's method
Journal of Computational Physics - Special issue: commenoration of the 30th anniversary
A unified coordinate system for solving the two-dimensional Euler equations
Journal of Computational Physics
A hybrid particle-continuum method applied to shock waves
Journal of Computational Physics
A unified moving grid gas-kinetic method in Eulerian space for viscous flow computation
Journal of Computational Physics
A hybrid particle approach for continuum and rarefied flow simulation
Journal of Computational Physics
Fluid simulations with localized boltzmann upscaling by direct simulation Monte-Carlo
Journal of Computational Physics
| Hi-index | 31.46 |
A new particle method is presented for the numerical simulation of compressible inviscid gas flows, through procedures which involve relatively small modifications to an existing direct simulation Monte Carlo (DSMC) algorithm. Implementation steps are outlined for simulations involving various grid geometries and for gas mixtures comprising an arbitrary number of species. The proposed method is compared with other numerical schemes through a series of one-dimensional and two-dimensional test cases, and is shown to provide a significant reduction in both artificial diffusion and statistical scatter effects relative to existing DSMC-based equilibrium particle methods.