A micro-macro coupling approach of MD-SPH method for reactive energetic materials

• Published in: AIP conference proceedings Vol. 1793; no. 1
• Main Authors: Liu, Gui Rong, Wang, Guang Yu, Peng, Qing, De, Suvranu
• Format: Journal Article Conference Proceeding
• Language: English
• Published: Melville American Institute of Physics 13.01.2017
• Subjects: Computational fluid dynamics; Computer simulation; Coupling (molecular); Detonation; Energetic materials; Equations of state; Experiments; Explosions; Explosives; Fluid flow; Growth models; HMX; Ignition; Mathematical models; Molecular dynamics; Quantum mechanics; Simulation; Smooth particle hydrodynamics
• ISSN: 0094-243X; 1551-7616
• DOI: 10.1063/1.4971540

The simulation of reactive energetic materials has long been the interest of researchers because of the extensive applications of explosives. Much research has been done on the subject at macro scale in the past and research at micro scale has been initiated recently. Equation of state (EoS) is the relation between physical quantities (pressure, temperature, energy and volume) describing thermodynamic states of materials under a given set of conditions. It plays a significant role in determining the characteristics of energetic materials, including Chapman-Jouguet point and detonation velocity. Furthermore, EoS is the key to connect microscopic and macroscopic phenomenon when simulating the macro effects of an explosion. For instance, an ignition and growth model for high explosives uses two JWL EoSs, one for solid explosive and the other for gaseous products, which are often obtained from experiments that can be quite expensive and hazardous. Therefore, it is ideal to calculate the EoS of energetic materials through computational means. In this paper, the EoSs for both solid and gaseous products of β-HMX are calculated using molecular dynamics simulation with ReaxFF-d3, a reactive force field obtained from quantum mechanics. The microscopic simulation results are then compared with experiments and the continuum ignition and growth model. Good agreement is observed. Then, the EoSs obtained through micro-scale simulation is applied in a smoothed particle hydrodynamics (SPH) code to simulate the macro effects of explosions. Simulation results are compared with experiments.