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Assessing Energy Budget of Laboratory Fault Slip Using Rotary Shear Experiments and Micro‐Computed Tomography

Qi Zhao, Steven D. Glaser, Nicola Tisato, Giovanni Grasselli

2020Geophysical Research Letters17 citationsDOIOpen Access PDF

Abstract

Abstract Quantitative assessment of the energy budget of earthquake events is one of the key aspects for understanding the physics of earthquakes. Investigation of laboratory fault slips under controlled conditions can provide insights on this important aspect of the natural and induced earthquakes. We conducted a rotary shear experiment under X‐ray micro‐computed tomography, which allowed in situ and operando measurement of macroscopic stresses and imaging of the newly formed fractures inside the sample. We estimate each component of the energy budget and found that friction energy loss ( E F ), fracture energy ( E G ), and radiated energy ( E R ) account for 70.16%, 15.68%, and 14.15% of the total energy budget, respectively. Quantitative analysis of the micro‐computed tomography images indicates that the energy consumed by creating slip‐induced off‐fault fractures ( ) accounts for only 0.3% of the total energy, less than 2% of the total E G .

Topics & Concepts

Energy budgetShear (geology)Energy (signal processing)TomographySlip (aerodynamics)SeismologyComputed tomographyGeologyFault (geology)PhysicsEngineeringAerospace engineeringStatisticsOpticsPetrologyMathematicsRadiologyMedicineThermodynamicsearthquake and tectonic studiesHigh-pressure geophysics and materialsSeismic Waves and Analysis
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