CHENILLE: Coupled Behavior Understanding of Faults: from the Laboratory to the Field

Q2 Earth and Planetary Sciences

Advances in Geosciences Pub Date : 2023-03-17 DOI:10.5194/adgeo-58-177-2023

Audrey Bonnelye, Pierre Dick, Marco Bohnhoff, Fabrice Cotton, Rüdiger Giese, Jan Henninges, Damien Jougnot, Grzegorz Kwiatek, Stefan Lüth

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引用次数: 0

Abstract

Abstract. The understanding of coupled thermo-hydro-mechanical behaviour of fault zones or in naturally fractured reservoirs is essential both for fundamental and applied sciences and in particular for the safety assessment of radioactive waste disposal facilities. The overall objective of the CHENILLE project is to better understand the physical processes resulting from thermal and hydraulic loading in a small fault zone in a highly consolidated shale formation. Consequently, a thermally controlled in-situ fluid injection experiment is intended to be performed on a strike-slip fault zone outcropping at the Tournemire/France Underground Research Laboratory (URL). A heating system has been installed around the injection area to enable a precise and controlled incremental increase of the thermal load. Different monitoring systems are designed to measure the seismic and aseismic deformation induced either by thermal and/or by hydraulic loading. The seismic monitoring system is composed of Acoustic Emission (AE) and broadband seismic sensors enabling monitoring of seismic fracturing processes down to sub-decimetre scale as well as slow deformation processes. Furthermore, we are about to install an injection chamber allowing to perform a controlled gaz injection test. The injection borehole will also be partly equipped with fiber optics in order to measure temperature in a distributed manner in the borehole. Time-lapse active seismic surveys are scheduled for before and after the experiment to image the structural network but also to detect the appearance of new structures triggered from the hydro-thermal pressurization of the fault as well as eventual changes in the velocity field.

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雪尼尔:故障的耦合行为理解:从实验室到现场

摘要了解断层带或天然裂缝储层的热-水-力学耦合行为对基础科学和应用科学，特别是对放射性废物处理设施的安全评估都是必不可少的。CHENILLE项目的总体目标是更好地了解在高度固结的页岩地层的小断层带中，由热载荷和水力载荷引起的物理过程。因此，在Tournemire/France地下研究实验室(URL)的走滑断裂带露头上进行了一项热控原位流体注入实验。在注入区域周围安装了加热系统，以实现精确和可控的热负荷增量增加。设计了不同的监测系统来测量由热载荷和/或水力载荷引起的地震和地震变形。地震监测系统由声发射(AE)和宽带地震传感器组成，能够监测亚分米尺度的地震压裂过程以及缓慢的变形过程。此外，我们即将安装一个注射室，允许进行受控的气体注射测试。注入井眼还将部分配备光纤，以便在井眼内以分布式方式测量温度。在实验前后计划进行时移主动地震调查，以对构造网进行成像，并检测由断层的热液加压引发的新构造的外观以及速度场的最终变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advances in Geosciences Earth and Planetary Sciences-Earth and Planetary Sciences (miscellaneous)

CiteScore

3.70

自引率

0.00%

发文量

审稿时长

30 weeks

期刊介绍： Advances in Geosciences (ADGEO) is an international, interdisciplinary journal for fast publication of collections of short, but self-contained communications in the Earth, planetary and solar system sciences, published in separate volumes online with the option of a publication on paper (print-on-demand). The collections may include papers presented at scientific meetings (proceedings) or articles on a well defined topic compiled by individual editors or organizations (special publications). The evaluation of the manuscript is organized by Guest-Editors, i.e. either by the conveners of a session of a conference or by the organizers of a meeting or workshop or by editors appointed otherwise, and their chosen referees.