Applicability of the Zintl Concept to Understanding the Crystal Chemistry of Lithium-Rich Germanides and Stannides.
Kowsik GhoshSalina RahmanAlexander OvchinnikovSvilen BobevPublished in: Inorganic chemistry (2024)
With this contribution, we take a new, critical look at the structures of the binary phases Li 5 Ge 2 and Li 5 Sn 2 . Both are isostructural (centrosymmetric space group R 3̅ m , no. 166), and in their structures, all germanium (tin) atoms are dimerized. Application of the valence rules will require the allocation of six additional valence electrons per [Ge 2 ] or [Sn 2 ] unit considering single covalent bonds, akin to those in the dihalogen molecules. Alternatively, four additional valence electrons per [Ge 2 ] or [Sn 2 ] anion will be needed if homoatomic double bonds exist, in an analogy with dioxygen. Therefore, five lithium atoms in one formula unit cannot provide the exact number of electrons, leaving open questions as to what is the nature of the chemical bonding within these moieties. Additionally, by means of single-crystal X-ray diffraction, synchrotron powder X-ray diffraction, and neutron powder diffraction, we established that the Li and Sn atoms in Li 5 Sn 2 are partially disordered, i.e., the actual chemical formula of this compound is Li 5- x Sn 2+ x (0 < x < 0.1). The convoluted atomic bonding in the case where tin atoms partially displace lithium atoms results in the formation of larger covalently bonded fragments. Our first-principle calculations suggest that such disorder leads to electron doping. Contrary to that, both experimental and computational findings indicate that in the Li 5 Ge 2 structure, the [Ge 2 ] dimers are slightly oxidized, i.e., hole-doped, as a result of approximately 30% vacancies on a Li site, i.e., the actual chemical formula of this compound is Li 5- x Ge 2 ( x ≈ 0.3).