Binding between endohedral Na atoms in Si clathrate I; a first principles study

Abstract

We investigate the binding nature of the endohedral sodium atoms with the ensity functional theory methods, presuming that the clathrate I consists of a sheaf of one-dimensional connections of Na@Si24 cages interleaved in three perpendicular directions. Each sodium atom loses 30% of the 3s1 charge to the frame, forming an ionic bond with the cage atoms; the rest of the electron contributes to the covalent bond between the nearest Na atoms. The presumption is proved to be valid; the configuration of the two Na atoms in the nearest Si24 cages is more stable by 0.189 eV than that in the Si20 and Si24 cages. The energy of the beads of the two distorted Na atoms is more stable by 0.104 eV than that of the two infinitely separated Na atoms. The covalent bond explains both the preferential occupancies in the Si24 cages and the low anisotropic displacement parameters of the endohedral atoms in the Si24 cages in the [100] directions of the clathrate I.