Accession Number : ADA305473

Title :   A Molecular Dynamics Study of Detonation. 1. A Comparison with Hydrodynamic Predictions.

Descriptive Note : Final rept. Jan 94-Aug 95,

Corporate Author : ARMY RESEARCH LAB ABERDEEN PROVING GROUND MD

Personal Author(s) : Rice, Betsy M. ; Mattson, William ; Grosh, John ; Trevino, S. F.

PDF Url : ADA305473

Report Date : MAR 1996

Pagination or Media Count : 50

Abstract : We have compared the predictions of hydrodynamic theory for the properties of an unsupported detonation with the results of a molecular dynamics simulation of such a phenomenon. The model of an energetic crystal consists of heteronuclear diatomic molecules which require energy to break the molecular bonds (at ambient pressure) and release substantial energy upon association of the products to form homonuclear diatomic molecules. The equation of state used in the hydrodynamic theory is determined from two-dimensional molecular dynamics simulations of this model at various equilibrium conditions corresponding to volumes and temperatures appropriate to the detonation. The Chapman-Jouguet conditions of detonation were thus determined. The properties of the detonation were subsequently measured directly from two-dimensional molecular dynamics simulations of the crystal model subjected to shock initiation. The agreement between the hydrodynamic predictions and the measured properties is good. Deviations from exact agreement are attributed to slight differences in material composition in the detonation simulation compared to that of the equation-of-state calculations. The critical property for sustained detonation using this model appears to be the attainment of the Chapman-Jouguet density. jg p3

Descriptors :   *DYNAMICS, *HYDRODYNAMICS, *MOLECULAR PROPERTIES, *DETONATIONS, SIMULATION, COMPUTATIONS, PREDICTIONS, MODELS, MOLECULES, TWO DIMENSIONAL, MATERIALS, CRYSTALS, CHEMICAL BONDS, SHOCK, PRESSURE, DIATOMIC MOLECULES, ENERGETIC PROPERTIES, COMPOSITION(PROPERTY), CHEMICAL EQUILIBRIUM, EQUATIONS OF STATE, NUCLEAR PROPERTIES.

Subject Categories : Explosions
      Physical Chemistry
      Fluid Mechanics
      Atomic and Molecular Physics and Spectroscopy

Distribution Statement : APPROVED FOR PUBLIC RELEASE