Control Mechanisms for Self‐Sealing in Activated Clay‐Rich Faults Through Controlled Hydraulic Injection Experiment

Control Mechanisms for Self‐Sealing in Activated Clay‐Rich Faults Through Controlled Hydraulic Injection Experiment

Abstract In a high‐pressure injection fault activation experiment conducted at the Mont Terri underground research laboratory in Switzerland, the transmissivity of the Opalinus Clay fault significantly increased due to opening and shearing. The fluid injection, spanning a few hours, generated a 10 m...

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Main Authors: Yves Guglielmi, Frédéric Cappa, Tanner Shadoan, Jonathan Ajo‐Franklin, Florian Soom, Bill Lanyon, Paul Cook, Chet Hopp, Verónica Rodríguez Tribaldos, Michelle Robertson, Todd Wood, Craig Ulrich, Senecio Schefer, Christophe Nussbaum, Jens Birkholzer
Format: Article
Language:English
Published: Wiley 2025-04-01
Series:Water Resources Research
Subjects:
fault
self‐sealing
transmissivity
plastic shear
swelling
long‐term
Online Access:https://doi.org/10.1029/2024WR037595
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Summary:Abstract In a high‐pressure injection fault activation experiment conducted at the Mont Terri underground research laboratory in Switzerland, the transmissivity of the Opalinus Clay fault significantly increased due to opening and shearing. The fluid injection, spanning a few hours, generated a 10 m radius fault activation patch. Subsequent pressure pulse tests conducted bi‐weekly for a year revealed the gradual return of fault transmissivity to its initial state. The study utilized fluid pressure decay analysis, optical fiber monitoring, continuous active source seismic measurements and borehole displacement sensors for measuring fault displacements. The fault zone exhibited a dilation of approximately 1.4 mm, associated with both normal and tangential movements during activation, resulting in a sudden transmissivity increase from 1 × 10−12 to 3.2 × 10−7 m2/s. Early post‐activation, transient compaction and the subsequent slow compaction were observed, transitioning to an extension regime. The pressure pulse tests demonstrated a rapid transmissivity drop by more than two orders of magnitude within the first 10 days, followed by a gradual and less pronounced decrease. Plastic shear and compaction dominated the transmissivity evolution until 70 days after injection ended, followed by a period where additional factors, such as clay mineral swelling, influenced the behavior. Extrapolation suggested a sealing process taking at least 50 years after the initial activation.
ISSN:0043-1397
1944-7973

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