Break-down of the relationship between {\alpha}-relaxation and equilibration in hydrostatically compressed metallic glasses

• Published in: arXiv.org
• Main Authors: Cornet, Antoine, Shen, Jie, Ronca, Alberto, Li, Shubin, Neuber, Nico, Frey, Maximilian, Pineda, Eloi, Deschamps, Thierry, Martinet, Christine, Sylvie Le Floch, Cangialosi, Daniele, Chushkin, Yuriy, Zontone, Federico, Cammarata, Marco, Vaughan, Gavin B M, Marco di Michiel, Garbarino, Gaston, Busch, Ralf, Gallino, Isabella, Goujon, Celine, Legendre, Murielle, Manthilake, Geeth, Ruta, Beatrice
• Format: Paper
• Language: English
• Published: Ithaca Cornell University Library, arXiv.org 20.09.2024
• Subjects: Amorphous materials; Atomic structure; Glass transition temperature; Hydrostatic compression; Metallic glasses; Structural stability; Thermodynamics
• ISSN: 2331-8422

It is usually assumed that the memory of any thermo-mechanical protocol applied to a glass can be erased by heating the material in the supercooled liquid. While this is true for thermally treated amorphous solids, we show that hydrostatic compression can irreversibly modify the atomic motion, thermodynamic state and structure of a prototypical metallic glass-former, in a way which depends on the degree of ergodicity reached by the material during compression. While enhanced kinetic and thermodynamic stability can be obtained by quenching the dense liquid, high-pressure annealing in the glass leads to thermal rejuvenation and complex structural rearrangements at the level of the short and medium range order. When heated above their glass transition temperature, these compressed glasses do not convert into the pristine supercooled liquid but rather transform into different systems, challenging the generally accepted idea of an equilibrium recovery controlled solely by the microscopic \(\alpha\)-relaxation process.