The elastic, mechanical, and thermodynamic properties of NaXH4 (X = B, Al) intended for the storage of hydrogen: An ab-initio study

Analyses based on first-principles simulations have revealed new details about the mechanical and thermody-namic characteristics of NaBH4 and NaAlH4 complex hydrides in alpha, beta and gamma phases. Using the quasi-harmonic Debye model, thermal parameters like the Debye temperature, the heat capacity, and the thermal expansion coefficient of NaXH4 (X = B, Al) complex hydrides are calculated in alpha, beta and gamma phases at different pressures and temperatures for the first time. Single-crystal elastic constants may be derived from the stress-strain relationship calculations. Although NaBH4 has a stronger compressibility modulus than NaAlH4, the distance dB-H is shorter than dAl-H, which may be explained by the presence of the covalent bond in BH4 and AlH4 in NaXH4 (X = B, Al). The melting points of NaXH4 (X = B, Al) may be used to estimate the decomposition temperatures of hydrogen. beta-NaXH4 has a higher melting point than alpha-NaXH4. Thus, the decomposition temperature of NaXH4 at which hydrogen is released from a fuel cell is expected to be lower than that of NaBH4. beta-NaBH4 has a more directed bonding tendency than alpha-NaAlH4 does. Except for the phase gamma-NaAlH4, the NaXH4 (X = B, Al) compounds are ductile. NaBH4 deforms more than NaAlH4 in uniaxial deformation, yet both are centrally strong solids. Our PBE calculations result in the linear compressibility and orientation-dependent Young's modulus. Tetragonal beta-NaBH4 and alpha-NaAlH4 structures have an isotropic bulk modulus but an anisotropic Young's modulus.