FPIC3D - a parallel code for modeling the high-energy processes in condensed matter

Authors

  • V.G. Sultanov

Keywords:

parallel programming
ions beams
parallel algorithms of ion energy deposition
equation of heat conductivity
realistic thermodynamic models
elastoplastic and fracture properties

Abstract

The FPIC3D finite-size particles in cell gas dynamic code for the numerical modeling of high-energy-density phenomena in condensed matter is considered. The parallel numerical schemes in use and the test results obtained with the aid of Russian super computers are discussed. The action of intense ion beams on targets is studied numerically. The paper was prepared on the basis of the author’s report at the International Conference on Parallel Computing Technologies


Published

2009-03-10

Issue

Section

Section 1. Numerical methods and applications

Author Biography

V.G. Sultanov


References

  1. Ким В.В., Ломоносов И.В., Острик А.В., Фортов В.Е. Метод конечно-размерных частиц в ячейке для численного моделирования высокоэнергетических импульсных воздействий на вещество // Математическое моделирование. 2006. 18, № 8. 5-11.
  2. Fortov V.E., Kim V.V., Lomonosov I.V., Matveichev A.V., Ostrik A.V. Numerical modeling of hypervelocity impacts // Int. J. Imp. Eng. 2006. 33. 244-253.
  3. Fortov V.E., Lomonosov I.V. Thermodynamics of extreme states of matter // J. Pure and Appl Chem. 1997. 69. 893-904.
  4. Lomonosov I.V. Multi-phase equation of state for aluminum // Laser and Particle Beams. 2007. 26. 567-584.
  5. Канель Г.И., Разоренов С.В., Уткин А.В., Фортов В.Е. Ударно-волновые явления в конденсированных средах. М.: Янус-К, 1996.
  6. Ziegler J.F., Biersack J.P., Littmark U. The stopping and range of ions in solids. New York: Pergamon Press, 1985.
  7. Tahir N.A., Deutsch C., Fortov V.E., Gryaznov V., Hoffmann D.H. H., Kulish M., Lomonosov I.V., Mintsev V., Ni P., Nikolaev D., Piriz A.R., Shilkin N., Spiller P., Shutov A., Temporal M., Ternovoi V., Udrea S., Varentsov D. Proposal for the study of thermophysical properties of high-energy-density matter using current and future heavy-ion accelerator facilities at GSI Darmstadt // Phys. Rev. Letters. 2005. 95, № 3. 035001-1-035001-4.
  8. Tahir N.A., Kain V., Schmidt R., Shutov A., Lomonosov I.V., Gryaznov V., Piriz A.R., Temporal M., Hoffmann D.H. H., Fortov V.E. The CERN large hadron collider as a tool to study high-energy density matter // Phys. Rev. Letters. 2005. 94, № 13. 135004-1-135004-4.
  9. Tahir N.A., Schmidt R., Brugger M., Lomonosov I.V., Shutov A., Piriz A.R., Udrea S., Hoffmann D.H. H., Deutsch C. Prospects of high energy density physics research using the CERN super proton synchrotron (SPS) // Laser and Particle Beams. 2007. 25. 639-647.
  10. Tahir N.A., Kim V., Lomonosov I.V., Grigoriev D.A., Piriz A.R., Weick H., Geissel H., Hoffmann D.H. H. High-energy density physics problems related to liquid jet lithium target for Super-FRS fast extraction scheme // Laser and Particle Beams. 2007. 25. 295-304.
  11. Tahir N.A., Kim V.V., Matveichev A.V., Ostrik A.V., Shutov A.V., Lomonosov I.V., Piriz A.R., Lopez Cela J.J., Hoffmann D.H. H. High-energy density and beam induced stress related issues in solid graphite Super-FRS fast extraction targets // Laser and Particle Beams. 2008. 26. 273-286.
  12. Tahir N.A., Weick H., Shutov A., Kim V., Matveichev A., Ostrik A., Sultanov V., Lomonosov I.V., Piriz A.R., Lopez Cela J.J., Hoffmann D.H. H. Simulations of a solid graphite target for high intensity fast extracted uranium beams for the Super-FRS // Laser and Particle Beams. 2008. 26. 411-423.