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Nuclear Theory
Colloquium
Venue: Physics Building, Max-von-Laue-Str. 1, Seminar Room PHYS 2.116
Time: Thursday, November 22, 3:30pm (s.t.)
Contact: hees@th.physik.uni-frankfurt.de
Quadrature methods in kinetic theory:
Limitations of the relaxation time approximation
Victor Ambrus (West University of Timisoara,
Romania)
During this talk, the capabilities of the relaxation time approximation
(RTA) for the Boltzmann collision integral are assessed in the context
of some benchmark problems. After briefly introducing the quadrature
techniques employed for numerical computations, the following
applications are summarised:
- Van der Waals and Cahn-Hilliard models for multiphase and
multicomponent flows.
- Rarefied gas flows through micro-channels: RTA vs DSMC for Maxwell
molecules and ab initio potentials, in the context of planar Couette
flow.
- Shock wave propagation: RTA vs DSMC for hard spheres and ab initio
potentials, in the standing shock problem.
- Relativistic fluid dynamics: longitudinal wave damping and
relativistic transport coefficients; RTA vs BAMPS for planar shock
wave propagation; Bjorken flow.
Nuclear
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