First Principles Study of the Electronic and Vibrational Properties of LiNbO2
Abstract
In the layered transition metal oxide LiNbO2 the Nb3+ (4d2) ion is trigonal-prismatically coordinated with O ions, with the resulting crystal field leading to a single band system for low energy properties. A tight-binding representation shows that intraplanar second neighbor hopping t2 = 100 meV dominates the first neighbor interaction (t1 = 64 meV). The first and third neighbor couplings are strongly modified by oxygen displacements of the symmetric Raman-active vibrational mode, and electron-phonon coupling to this motion may provide the coupling mechanism for superconductivity in Li-deficient samples (where Tc = 5 K). We calculate all zone-center phonon modes, identify infrared (IR) and Raman active modes, and report LO-TO splitting of the IR modes. The Born effective charges for the metal ions are found to have considerable anisotropy reflecting the degree to which the ions participate in interlayer coupling and covalent bonding. Insight into the microscopic origin of the valence band density, composed of Nb dz2 states with some mixing of O 2p states, is obtained from examining Wannier functions for these bands.
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