Investigating Criticality in Rock Failure Using Fiber-Optic Strain Sensing

IF 4.6 1区地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY

Geophysical Research Letters Pub Date : 2025-07-19 DOI:10.1029/2025GL115010

Hao Chen, Paul Antony Selvadurai, Tom de Geus, Antonio Felipe Salazar Vásquez, Patrick Bianchi, Sofia Michail, Markus Rast, Claudio Madonna, Stefan Wiemer

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Abstract

Gradual localization of deformation preceding catastrophic failure can produce precursory signals associated with a phase transition that may be present prior to earthquakes. However, due to the unclear origin of these precursors and the complexity of the environmental conditions, detecting such preparatory signals remains challenging. Here we present the spatio-temporal evolution of surface strain measured using fiber-optic sensing during triaxial experiments in wet and dry conditions. We identify a power-law distribution of strain increments where the largest magnitude diverges toward failure. This suggests a critical phase transition with the emergence of failure precursors. However, criticality is only observed in dry conditions and disappears with pressurized pore fluids, where the largest strain increment accelerates exponentially, consistent with a first-order transition. Our results highlight that progressive damage features criticality for failure prediction, but elevated fluid pressures may shift this behavior to abrupt rupture.

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利用光纤应变传感技术研究岩石破坏的临界状态

在灾难性破坏之前，变形的逐渐局部化可以产生与地震之前可能出现的相变相关的前兆信号。然而，由于这些前体的来源不清楚以及环境条件的复杂性，探测这些预备信号仍然具有挑战性。在这里，我们介绍了在干湿条件下三轴实验中使用光纤传感测量的表面应变的时空演变。我们确定了应变增量的幂律分布，其中最大的幅度向失败发散。这表明随着失效前体的出现，存在一个临界相变。然而，临界只在干燥条件下观察到，而在加压孔隙流体中消失，其中最大应变增量呈指数级加速，符合一阶转变。我们的研究结果强调了渐进式损伤对失效预测的重要性，但升高的流体压力可能会将这种行为转变为突然破裂。

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来源期刊

Geophysical Research Letters 地学-地球科学综合

CiteScore

9.00

自引率

9.60%

发文量

1588

审稿时长

2.2 months

期刊介绍： Geophysical Research Letters (GRL) publishes high-impact, innovative, and timely research on major scientific advances in all the major geoscience disciplines. Papers are communications-length articles and should have broad and immediate implications in their discipline or across the geosciences. GRLmaintains the fastest turn-around of all high-impact publications in the geosciences and works closely with authors to ensure broad visibility of top papers.