Incomplete molecular chaos within dense-fluid shock waves

Abstract: Large-scale molecular dynamics simulations of a M s = 4.3 shock in dense argon (ρ = 532 kg/m 3 , T = 300 K) and a M s = 3.6 shock in dense nitrogen (ρ = 371 kg/m 3 , T = 300 K) have been per-

“…100, 000 nitrogen molecules are randomly distributed within the fluid portion of the domain and given random initial velocities and rotation rates drawn from a Maxwell-Boltzmann distribution. The rigid nitrogen molecule is modeled by a two-center Lennard-Jones (6,12) potential with the parameters as given in Ref. [22], but without the five point-charges.…”

“…4 through 7 will then discuss one phenomenon which has only recently come to light (see Refs. [10][11][12], respectively, for more details). These are all aspect of a broader research project carried out over the last several years at ETH Zurich [13].…”

Atomistic phenomena in dense fluid shock waves

“…100, 000 nitrogen molecules are randomly distributed within the fluid portion of the domain and given random initial velocities and rotation rates drawn from a Maxwell-Boltzmann distribution. The rigid nitrogen molecule is modeled by a two-center Lennard-Jones (6,12) potential with the parameters as given in Ref. [22], but without the five point-charges.…”

“…4 through 7 will then discuss one phenomenon which has only recently come to light (see Refs. [10][11][12], respectively, for more details). These are all aspect of a broader research project carried out over the last several years at ETH Zurich [13].…”

Atomistic phenomena in dense fluid shock waves

Molecular dynamics of shock waves in dense fluids

Structure of Shock Waves in Dense Media