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The vibrational, thermodynamic and mechanical properties of four types HMX based on the first-principles study

Han Qin, Wei Zeng, Fusheng Liu, Yun-Dan Gan, Bin Tang, Sheng‐Hai Zhu, Qi‐Jun Liu

2020Journal of Energetic Materials20 citationsDOI

Abstract

The vibrational, thermodynamic and mechanical properties of α-, β-, δ-, and γ-HMX are investigated based on the first principle method. The calculated lattice parameters of four types HMX based on the GGA-PBE+G functional are in good agreement with the experimental values and our pervious calculated values. The phonon density of states and vibrational properties of HMX are obtained. In the lower or higher vibrational region, the molecular motions are in certain NO2 or CH2 group. In the middle region, the motions are widely distributed in different group. Besides, the thermodynamic properties such as Helmholtz free energy (F), entropy (S), enthalpy (H), Gibbs free energy (G) and heat capacities (Cv) are obtained. The results of Debye temperatures show that the most stable β-HMX is going to be unstable when the temperature increases. The elastic constants of α-, β- and δ-HMX are calculated and compared with previous calculated results. The elastic constants of γ-HMX are obtained for the first time. Furthermore, the mechanical properties including bulk modulus (B), shear modulus (S), Young’s modulus (G), Poisson’s ratio (ν), B/G value and universal anisotropy index (AU) are also calculated. We find that α-HMX and β-HMX possess brittle behavior while δ-HMX and γ-HMX are ductile. The anisotropy of γ-HMX is the smallest and the anisotropy of β-HMX is the biggest.

Topics & Concepts

ThermodynamicsHelmholtz free energyDebye modelBulk modulusShear modulusHeat capacityAnisotropyGibbs free energyEnthalpyMaterials scienceGrüneisen parameterThermodynamic databases for pure substancesChemistryMaterial propertiesThermal expansionPhysicsThermodynamic processQuantum mechanicsEnergetic Materials and CombustionThermal and Kinetic AnalysisNonlinear Optical Materials Research