Constitutive modelling of the densification process in silica glass under hydrostatic compression

TL;DR

This paper develops an elastic-plastic constitutive model for silica glass under high hydrostatic pressure, accurately capturing densification, elastic moduli changes, and experimental pressure-volume responses up to 25 GPa.

Contribution

The paper introduces a new constitutive model for silica glass densification under high pressure, calibrated with experimental data and validated against in situ measurements.

Findings

Model captures densification onset and saturation

Elastic moduli increase with pressure

Accurately reproduces pressure-volume response

Abstract

The mechanical response of amorphous silica (or silica glass) under hydrostatic compression for very high pressures up to 25 GPa is modelled via an elastic-plastic constitutive equation (continuum mechanics framework).The material parameters appearing in the theory have been estimated from the ex situ experimental data from Rouxel et al. [Rouxel T, Ji H, Guin JP, Augereau F, Ruffle B J Appl Phys 2010;107(9):094903]. The model is shown to capture the major features of the pressure-volume changes response from the in situ experimental work of Sato and Funamori [Sato T, Funamori N Phys Rev Lett 2008;101:255502]. In particular, the onset and saturation of densification, the increase in elasticity parameters (bulk, shear and Youngs moduli) and Poissons ratio are found to be key parameters of the model.