Real time observation of granular rock analogue material deformation and failure using nonlinear laser interferometry

TL;DR

This study introduces a real-time, high-resolution laser interferometry method to observe granular rock deformation and failure, revealing early warning signals of fracture through vibrational analysis.

Contribution

The paper presents a novel nonlinear self-mixing interferometry technique for real-time monitoring of geomaterial deformation and failure prediction.

Findings

Vibrational period variation precedes failure.

Material response becomes irreversible after multiple shocks.

Critical slowing down signals impending fracture.

Abstract

A better understanding and anticipation of natural processes such as landsliding or seismic fault activity requires detailed theoretical and experimental analysis of rock mechanics and geomaterial dynamics. These last decades, considerable progress has been made towards understanding deformation and fracture process in laboratory experiment on granular rock materials, as the well-known shear banding experiment. One of the reasons for this progress is the continuous improvement in the instrumental techniques of observation. But the lack of real time methods does not allow the detection of indicators of the upcoming fracture process and thus to anticipate the phenomenon. Here, we have performed uniaxial compression experiments to analyse the response of a granular rock material sample to different shocks. We use a novel interferometric laser sensor based on the nonlinear self-mixing interferometry technique to observe in real time the deformations of the sample and assess its usefulness as a diagnostic tool for the analysis of geomaterial dynamics. Due to the high spatial and temporal resolution of this approach, we observe both vibrations processes in response to a dynamic loading and the onset of failure. The latter is preceded by a continuous variation of vibration period of the material. After several shocks, the material response is no longer reversible and we detect a progressive accumulation of irreversible deformation leading to the fracture process. We demonstrate that material failure is anticipated by the critical slowing down of the surface vibrational motion, which may therefore be envisioned as an early warning signal or predictor to the macroscopic failure of the sample. The nonlinear self-mixing interferometry technique is readily extensible to fault propagation measurements. As such, it opens a new window of observation for the study of geomaterial deformation and failure.