Electronic properties of metal induced gap states at insulator/metal interfaces -- dependence on the alkali halide and the possibility of excitonic mechanism of superconductivity
arXiv:cond-mat/0308155 · doi:10.1103/PhysRevB.69.115424
Abstract
Motivated from the experimental observation of metal induced gap states (MIGS) at insulator/metal interfaces by Kiguchi {\it et al.} [Phys. Rev. Lett. {\bf 90}, 196803 (2003)], we have theoretically investigated the electronic properties of MIGS at interfaces between various alkali halides and a metal represented by a jellium with the first-principles density functional method. We have found that, on top of the usual evanescent state, MIGS generally have a long tail on halogen sites with a $p_z$-like character, whose penetration depth ($λ$) is as large as half the lattice constant of bulk alkali halides. This implies that $λ$, while little dependent on the carrier density in the jellium, is dominated by the lattice constant (hence by energy gap) of the alkali halide, where $λ_{\rm LiF} < λ_{\rm LiCl} < λ_{\rm LiI}$. We also propose a possibility of the MIGS working favorably for the exciton-mediated superconductivity.
7 pages, 9 figures