Structural Characterization of Agl-AgPO3-Ag2WO4 Superionic Conducting Glasses by Advanced Solid-State NMR Techniques

Glass samples of composition 40AgI-(60-x)AgPO3-xAg(2)WO(4) (0 <= x <= 25 mol %) have been prepared by the conventional melt-quenching method. These glasses receive renewed interest due to their ionic conductivity, and transparency in the visible range. Because the physical and optical properties of these glasses are highly dependent on composition in this system, a comprehensive structural study has been carried out using Raman spectroscopy and ID and 2D NMR of the P-31 and Ag-109 nuclei. With increasing Ag2WO4 content, the network, is modified from a 1D Q((2))-like chain structure to a topology in which Q((1)) and Q((0)) species linked to octahedrally coordinated tungsten species dominate. This structural transformation increases the glass rigidity and stability against hydrolysis reactions. The compositional evolution of the phosphate speciation (in terms of Q((n)) mW units) is consistent with maximum tungstate dispersion in glasses with x <= 10; while for glasses with higher tungstate content the data are more consistent with a random distribution of P-O-P, P-O-W, and W-O-W linkages. The Ag-109 NMR chemical shifts are independent of composition and suggest that mobile silver ions are situated within cluster regions, furnishing a constant mixed iodide/oxide local environment.