• DocumentCode
    1506665
  • Title

    Time-Step Considerations in Particle Simulation Algorithms for Coulomb Collisions in Plasmas

  • Author

    Cohen, Bruce I. ; Dimits, Andris M. ; Friedman, Alex ; Caflisch, Russel E.

  • Author_Institution
    Lawrence Livermore Nat. Lab., Livermore, CA, USA
  • Volume
    38
  • Issue
    9
  • fYear
    2010
  • Firstpage
    2394
  • Lastpage
    2406
  • Abstract
    The accuracy of first-order Euler and higher-order time-integration algorithms for grid-based Langevin equations collision models in a specific relaxation test problem is assessed. We show that statistical noise errors can overshadow time-step errors and argue that statistical noise errors can be conflated with time-step effects. Using a higher-order integration scheme may not achieve any benefit in accuracy for examples of practical interest. We also investigate the collisional relaxation of an initial electron-ion relative drift and the collisional relaxation to a resistive steady-state in which a quasi-steady current is driven by a constant applied electric field, as functions of the time step used to resolve the collision processes using binary and grid-based, test-particle Langevin equations models. We compare results from two grid-based Langevin equations collision algorithms to results from a binary collision algorithm for modeling electron-ion collisions. Some guidance is provided on how large a time step can be used compared to the inverse of the characteristic collision frequency for specific relaxation processes.
  • Keywords
    differential equations; plasma collision processes; plasma simulation; plasma transport processes; Coulomb collision; binary collision algorithm; characteristic collision frequency; collisional relaxation; electron-ion collision model; electron-ion relative drift; first-order Euler algorithm; grid-based Langevin equation; high-order time-integration algorithm; particle simulation algorithm; quasisteady current; statistical noise error; test-particle Langevin equation model; time-step consideration; Computational modeling; Drag; Equations; Laboratories; Plasma applications; Plasma density; Plasma properties; Plasma simulation; Steady-state; Testing; Algorithms; collision processes; computer applications; numerical analysis; particle collisions; plasmas;
  • fLanguage
    English
  • Journal_Title
    Plasma Science, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0093-3813
  • Type

    jour

  • DOI
    10.1109/TPS.2010.2049589
  • Filename
    5475281