Long term aging of Selenide glasses: Evidence of sub-Tg endotherms and pre-Tg exotherms

TL;DR

This study investigates long-term aging effects in chalcogenide glasses, revealing sub-Tg endotherms and pre-Tg exotherms linked to nanoscale phase separation and network compaction, with aging behavior influenced by synthesis and environmental conditions.

Contribution

It provides new insights into aging phenomena in selenide glasses, distinguishing intrinsic and extrinsic effects, and clarifies the origin of sub-Tg and pre-Tg features through calorimetric and Raman analysis.

Findings

Sub-Tg endotherms are linked to network compaction.

Pre-Tg exotherms are associated with nanoscale phase separation.

Aging effects depend on sample preparation and environment.

Abstract

Long term aging is studied on several families of chalcogenide glasses including the Ge-Se, As-Se, Ge-P-Se and Ge-As-Se systems. Special attention is given to the As-Se binary, a system that displays a rich variety of aging behavior intimately tied to sample synthesis conditions and the ambient environment in which samples are aged. Calorimetric (Modulated DSC) and Raman scattering experiments are undertaken. Our results show all samples display a sub-Tg endotherm below Tg in glassy networks possessing a mean coordination number r in the 2.25 < r < 2.45 range. Two sets of AsxSe1-x samples aged for 8 years were compared, set A consisted of slow cooled samples aged in the dark, and set B consisted of melt quenched samples aged at laboratory environment. Samples of set B in the As concentration range, 35% < x < 60%, display a pre-Tg exotherm, but the feature is not observed in samples of set A. The aging behavior of set A presumably represents intrinsic aging in these glasses, while that of set B is extrinsic due to presence of light. The reversibility window persists in both sets of samples but is less well defined in set B. These findings contrast with a recent study by Golovchak et al., which finds the onset of the reversibility window moved up to the stoichiometric composition (x = 40%). Here we show that the upshifted window is better understood as resulting due to demixing of As4Se4 and As4Se3 molecules from the backbone, i.e., Nanoscale phase separation (NSPS). We attribute sub-Tg endotherms to compaction of the flexible part of networks upon long term aging, while the pre-Tg exotherm to NSPS. Finally, the narrowing and sharpening of the reversibility window upon aging is interpreted as the slow 'self-organizing' stress relaxation of the phases just outside the Intermediate phase.