Density functional study of electronic structure, elastic and optical properties of MNH < inf > 2 < /inf > (M=Li, Na, K, Rb)

Abstract

We report a systematic first principles density functional study on the electronic structure, elastic and optical properties of nitrogen based solid hydrogen storage materials LiNH2, NaNH2, KNH2, and RbNH2. The ground state structural properties are calculated by using standard density functional theory, and also dispersion corrected density functional theory. We find that vander Waals interactions are dominant in LiNH2 whereas they are relatively weak in other alkali metal amides. The calculated elastic constants show that all the compounds are mechanically stable and LiNH2 is found to be a stiffer material among the alkali metal amides. The melting temperatures are calculated and follow the order RbNH2 < KNH2 < NaNH2 < LiNH 2. Theelectronic band structure is calculated by using the Tran-Blaha modified Becke-Johnson potential and found that all the compounds are insulators, with a considerable band gap. The[NH2]- derived states completely dominate in the entire valence band region while the metal atom states occupy the conduction band. The calculated band structure is used to analyzethe different interband optical transitions occurring between valence and conduction bands. Ourcalculations show that these materials have considerable optical anisotropy. © 2014 IOP Publishing Ltd.