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High-Pressure Equation of State of 1,3,5-triamino-2,4,6-trinitrobenzene: Insights into the Monoclinic Phase Transition, Hydrogen Bonding, and Anharmonicity

Brad A. Steele, Elissaios Stavrou, Vitali B. Prakapenka, Matthew P. Kroonblawd, I‐Feng W. Kuo

2020The Journal of Physical Chemistry A26 citationsDOIOpen Access PDF

Abstract

The high-pressure equation of state (EOS) of energetic materials (EMs) is important for continuum and mesoscale models of detonation performance and initiation safety. Obtaining a high-fidelity EOS of the insensitive EM 1,3,5-triamino-2,4,6-trinitrobenzene (TATB) has proven to be difficult because of challenges in experimental characterization at high pressures (HPs). In this work, powder X-ray diffraction patterns were fitted using the recently discovered monoclinic I2/a phase above 4 GPa, which shows that TATB is less compressible than when indexed with the triclinic P1̅ phase. First-principles calculations were performed with Perdew–Burke–Ernzerhof (PBE) and PBE0 functionals including thermal effects using the P1̅ phase. PBE0 improves the description of hydrogen bonding and thus predicts accurate planar a and b lattice parameters under ambient conditions. However, discrepancies in the predicted lattice parameters above 4–10 GPa compared with experimental measurements indexed with P1̅ are further evidence of a structural modification at high pressure. Layer sliding defects are formed during molecular dynamics simulations, which induces an anharmonic effect on the thermal expansion of the c lattice parameter. In short, the results provide several insights into determining high-fidelity EOS parameters for TATB and other molecular crystals.

Topics & Concepts

TATBAnharmonicityMonoclinic crystal systemTriclinic crystal systemEquation of stateMaterials scienceThermodynamicsPhase transitionBulk modulusEnergetic materialHydrogen bondLattice (music)Molecular dynamicsPhase (matter)CrystallographyDetonationChemistryCrystal structureComputational chemistryCondensed matter physicsMoleculePhysicsExplosive materialOrganic chemistryAcousticsEnergetic Materials and CombustionHigh-pressure geophysics and materialsCrystallography and molecular interactions