The effects of Sn addition on properties and structure in Ge–Se chalcogenide glass

Abstract

Far infrared transmission spectra of homogeneous compositions in the glassy alloy system Ge 1− x Sn x Se 2.5 0⩽ x⩽0.6 have been observed in the spectral range 200–500 cm −1 at room temperature. The infrared absorption spectra show strong bands around 231, 284 and 311 cm −1 which were assigned to GeSe, SeSn, Se–Se. Tin atoms appear to substitute for the germanium atoms in the outrigger sites of Ge(Se 1/2) 4 tetrahedra up to 0.4. For x>0.5, the glasses show a new vibrational band of an isolated F 2 mode of the Ge-centered tetrahedra outside the clusters. A pronounced peculiarity (maximum or minimum) appeared at around the same value of the average coordination number at Z=2.65 for all composition dependence topological phase transition from two-dimensional (2D) layer type to three- dimensional (3D) cross-linked network structures in the glass. It is clear that the theoretical ν-values for Se–Se bond is less than the experimental one and that for Se–Ge is greater than the experimental one. This difference may be due to the existence of more close lying modes which tends to broaden the absorption bands. Quantitative justification of the absorption bands shows that theoretical wave numbers agree with its experimental values for Ge–Se stretching vibration bond.