Generalisation of the modified tight-binding approximation in transition metals

The electron-phonon interaction has been studied in the cubic transition metals using a tight-binding formalism. Accurate Slater-Koster fits to self-consistent, scalar-relativistic, augmented-plane-wave band calculations have been employed and scaling relations were used to determine gradients of th

## Abstract We study here several basic problems of the quantum mechanics of electrons which are embedded into a onedimensional (1D) nonlinear, thermally excited lattice. Our approach uses the tight‐binding model for the dynamics of the electrons. Through coupling terms in the Hamiltonian the elect

The modified electrostatic model is applied to diffusion of 3d-5d transition metals in noble metals. The comparison of experimental and calculated temperature dependence of the diffusion coefficients permits conclusions with respect to effective charges of solute atoms.

The electronic structures of Pd and Pt epitaxiai monolayers on Re and Ru (000 1) surfaces are studied within a self-consistent semi-empirical scheme. To this purpose an s-d-electron tight-binding Hamiltonian is treated by the recursion method. The overlayer d bands are shifted to higher binding ener