Unexpected non-monotonic changing in the heterogeneity of glasses during annealing

doi:10.1016/j.jmst.2023.07.071

Abstract

Abstract: The heterogeneity of glasses has critical influences on the properties. How heterogeneity evolves during annealing is an intriguing cutting-edge question. In this work, the heterogeneity of the annealed metallic and polymer glasses has been studied systematically by using stress relaxation and nanoindentation tests. The stress relaxation processes are analyzed using Kohlrausch-Williams-Watts (KWW) equation. We surprisingly find that the heterogeneous factor βKWW in KWW equation does not change monotonously but increases first and then decreases along with the annealing time. The two-stage process implies that glasses do not evolve as expected toward the more homogeneous glassy state but become homogeneous first and then more heterogeneous. This is further verified by the evolution of critical shear stress for local plasticity. It is revealed that the two-stage process is correlated with different relaxation modes, which is further interpreted using a phenomenological model. These findings not only give insights into understanding the nature of glasses, but also are useful for designing glasses with superior properties.

Key words: Glasses, Heterogeneity, Aging, Relaxation

Yu Tong, Fucheng Li, Lijian Song, Yanhui Liu, Juntao Huo, Jichao Qiao, J.M. Pelletier, Daniel Crespo, Eloi Pineda, Jun-Qiang Wang. Unexpected non-monotonic changing in the heterogeneity of glasses during annealing[J]. J. Mater. Sci. Technol., 2024, 177: 96-102.

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