Relaxation processes of densified silica glass

Cornet A, Martinez-Andrieux V, de Ligny D, Champagnon B, Martinet C (2017)


Publication Language: English

Publication Status: Published

Publication Type: Journal article, Original article

Publication year: 2017

Journal

Publisher: AMER INST PHYSICS

Book Volume: 146

Journal Issue: 9

DOI: 10.1063/1.4977036

Abstract

Densified SiO2 glasses, obtained from different pressure and temperature routes, have been annealed over a wide range of temperatures far below the glass transition temperature (500 degrees C-900 degrees C). Hot and cold compressions were useful to separate the effects of pressure and the compression temperature. In situ micro-Raman spectroscopy was used to follow the structural evolution during the thermal relaxation. A similar glass structure between the non-densified silica and the recovered densified silica after the temperature annealing demonstrates a perfect recovery of the non-densified silica glass structure. While the density decreases monotonically, the structural relaxation takes place through a more complex mechanism, which shows that density is not a sufficient parameter to fully characterize the structure of densified silica glass. The relaxation takes place through a transitory state, consisting in an increase of the network inhomogeneity, shown by an increase in the intensity of the D2 band which is associated with 3 membered rings. The activation energy of these processes is 255 +/- 45 kJ/mol for the hot compressed samples. The kinetic is overall faster for the cold compressed samples. In that last case, the relaxation is partially activated by internal stresses release. Published by AIP Publishing.

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APA:

Cornet, A., Martinez-Andrieux, V., de Ligny, D., Champagnon, B., & Martinet, C. (2017). Relaxation processes of densified silica glass. Journal of Chemical Physics, 146(9). https://dx.doi.org/10.1063/1.4977036

MLA:

Cornet, Antoine, et al. "Relaxation processes of densified silica glass." Journal of Chemical Physics 146.9 (2017).

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