PNNL

Abstract

The heats of formation for the boron amines BH3NH3, BH2NH2, and HBNH, tetrahedral BH4-, and the BN molecule have been calculated by using ab initio molecular orbital theory. Coupled cluster calculations with perturbative triples (CCSD(T)) were employed for the total valence electronic energies. Correlation consistent basis sets were used, up through the augmented quadruple zeta, to extrapolate to the complete basis set limit. Core/valence, scalar relativistic, and spin-orbit corrections were included in an additive fashion to predict the atomization energies. Geometries were calculated at the CCSD(T) level up through at least aug-cc-pVTZ and frequencies were calculated at the CCSD(T)/aug-cc-pVDZ level. The heats of formation at 0K in the gas phase are ?Hf(BH3NH3) = -9.1, ?Hf(BH2NH2) = -15.9, ?Hf(BHNH) = 13.6, ?Hf(BN) = 146.4, and ?Hf(BH4-) = -11.6 kcal/mol. The reported experimental value for ?Hf(BN) is clearly in error. The heat of formation of the salt [BH4-]NH4+] (s) has been estimated by using an empirical expression for the lattice energy and the calculated heats of formation of the two component ions. The calculations show that both BH3NH3(g) and [BH4-]NH4+](s) can serve as good hydrogen storage systems which release H2 in a slightly exothermic process. The hydride affinity of BH3 is calculated to be 72.2 kcal/mol in excellent agreement with the experimental value at 298K of 74.2 ± 2.8 kcal/mol.