Glass Transition and Infrared Spectra of Low‐Alkali, Anhydrous Lithium Phosphate Glasses

Abstract

Anhydrous glasses in the series xLi₂O + (1 ‐ x)P₂O₅ have been prepared and characterized in the range 0 ≤x≤ 0.5. FT‐IR spectroscopy and glass transition temperature measurements have been used to explore the structure and a key physical property of the low‐alkali phosphate glasses. The structure of v‐P₂O₅ is proposed to consist of a 3‐D network of trigonally connected tetrahedra decorated with a P=O unit. Contrary to what has long been proposed for these glasses, the addition of alkali degrades the 3‐D network through the generation of nonbridging oxygens rather than strengthen the network through the proposed alkali ion bridging. The T_g of v‐P₂O₅ is ∼653 K and decreases some 130 K with the addition of 10 mol% Li₂O. T_g then reaches a minimum value at 20 mol% Li₂O and increases with further Li₂O additions. The increase in T_g, even though the fraction of nonbridging oxygens is still increasing, is interpreted in terms of an increasing entanglement of long‐chain PO₂ groups in the glass. Such a structural transition from a 3‐D network of interconnected PO₄ groups for P₂O₅ to a 1‐D chain structure for LiPO₃ is one of the first examples of the importance of intermediate‐range order in governing the properties of glass.