We present a general, flexible framework for a constant-energy variant of the dissipative particle dynamics method that allows chemical reactions (DPD-RX). In our DPD-RX approach, reaction progress variables are assigned to each particle that monitor the time evolution of an extent-of-reaction associated with the prescribed reaction mechanisms and kinetics assumed to occur within the particle, where chemistry can be modeled using complex or reduced reaction mechanisms. We demonstrate our DPD-RX method by considering thermally initiated unimolecular decomposition of the energetic material, cyclotrimethylene trinitramine (RDX), into a molecular gas mixture. Studies are performed to demonstrate the effect of a spatially averaged particle internal temperature and a local reaction volume term in the chemical kinetics expressions, where both provide implicit mechanisms for capturing condensed phase reactivity. We also present an analysis of the expansion of the product gas mixture during decomposition. Finally, a discussion of other potential applications and extensions of the DPD-RX method is given.

Code 6189 Theoretical Chemistry Section U S Naval Research Laboratory Washington DC 20375 USA

Department of Molecular and Mesoscopic Modelling Institute of Chemical Process Fundamentals of the CAS Prague Czech Republic

Weapons and Materials Research Directorate U S Army Combat Capabilities Development Command Army Research Laboratory Aberdeen Proving Ground Maryland 21005 5066 USA

References provided by Crossref.org