Vlasov model using kinetic phase point trajectories
This work offers a computational technique for plasma physics simulations, but it is incremental as it builds on existing particle-in-cell and grid-based methods.
The paper presents a method for solving the Vlasov equation using kinetic phase point trajectories, showing that increasing the number of phase points improves accuracy without requiring finer grid resolution. The method avoids recurrence effects via randomized initial positions and is validated on linear Landau damping.
A method of solution of the collisionless Vlasov equation, by following collisionless phase point trajectories in phase space, is presented. It is shown that by increasing the number of phase points, without enhancing the resolution of phase space grid, the accuracy of simulation will be improved. Besides, the phase points spacing introduces a smaller scale than grid spacing on which fine structures might be more conveniently handled. In order to perform simulation with a large population of phase points, an effective interpolation scheme is introduced that reduces the number of operations. It is shown that by randomizing initial position of the phase points along velocity axis, the recurrence effect does not happen. Finally, the standard problem of linear Landau damping will be examined.