posted on 2023-08-17, 05:03authored byDana O’Connor, Imanuel Bier, Rithwik Tom, Anna M. Hiszpanski, Brad A. Steele, Noa Marom
Crystal structure prediction (CSP) is performed for the
energetic
materials (EMs) LLM-105 and α-RDX, as well as the α and
β conformational polymorphs of 1,3,5,7-tetranitro-1,3,5,7-tetraazacyclooctane
(HMX), using the genetic algorithm (GA) code, GAtor, and its associated
random structure generator, Genarris. Genarris and GAtor successfully
generate the experimental structures of all targets. GAtor’s
symmetric crossover scheme, where the space group symmetries of parent
structures are treated as genes inherited by offspring, is found to
be particularly effective. However, conducting several GA runs with
different settings is still important for achieving diverse samplings
of the potential energy surface. For LLM-105 and α-RDX, the
experimental structure is ranked as the most stable, with all of the
dispersion-inclusive density functional theory (DFT) methods used
here. For HMX, the α form was persistently ranked as more stable
than the β form, in contrast to experimental observations, even
when correcting for vibrational contributions and thermal expansion.
This may be attributed to insufficient accuracy of dispersion-inclusive
DFT methods or to kinetic effects not considered here. In general,
the ranking of some putative structures is found to be sensitive to
the choice of the DFT functional and the dispersion method. For LLM-105,
GAtor generates a putative structure with a layered packing motif,
which is desirable thanks to its correlation with low sensitivity.
Our results demonstrate that CSP is a useful tool for studying the
ubiquitous polymorphism of EMs and shows promise of becoming an integral
part of the EM development pipeline.