Effect of Geometry and Fluid Viscosity on Dynamics of Fluid‐Filled Cracks: Insights From Analog Experimental Observations

Effect of Geometry and Fluid Viscosity on Dynamics of Fluid‐Filled Cracks: Insights From Analog Experimental Observations

Abstract Fluid‐filled volumes in geological systems can change the local stress field in the host rock and may induce brittle deformation as well as crack propagation. Although the mechanisms relating fluid pressure perturbations and seismicity have been widely studied, the fluid‐solid interaction i...

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Bibliographic Details
Main Authors: Haitao Cao, Ezequiel F. Medici, Gregory P. Waite, Roohollah Askari
Format: Article
Language:English
Published: American Geophysical Union (AGU) 2020-11-01
Series:Earth and Space Science
Subjects:
crack
bubble nucleation
cavitation
crack dynamics
Online Access:https://doi.org/10.1029/2020EA001333
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spelling doaj-c57b36bdf1f9419284fa710b8e57f36c2021-03-01T10:41:56ZengAmerican Geophysical Union (AGU)Earth and Space Science2333-50842020-11-01711n/an/a10.1029/2020EA001333Effect of Geometry and Fluid Viscosity on Dynamics of Fluid‐Filled Cracks: Insights From Analog Experimental ObservationsHaitao Cao0Ezequiel F. Medici1Gregory P. Waite2Roohollah Askari3Department of Geological and Mining Engineering and Science Michigan Technological University Houghton MI USADepartment of Mechanical Engineering‐Engineering Mechanics Michigan Technological University Houghton MI USADepartment of Geological and Mining Engineering and Science Michigan Technological University Houghton MI USADepartment of Geological and Mining Engineering and Science Michigan Technological University Houghton MI USAAbstract Fluid‐filled volumes in geological systems can change the local stress field in the host rock and may induce brittle deformation as well as crack propagation. Although the mechanisms relating fluid pressure perturbations and seismicity have been widely studied, the fluid‐solid interaction inside the crack of a host rock is still not well understood. An analog experimental model of fluid intrusion in cracks between planar layers has been developed to study stress conditions at the margins and tips. A combined high‐speed shadowgraph and a photoelasticity imaging system is used to visualize the fluid dynamics and induced stresses on the solid matrix. Cavitation, as well as bubble growth and collapse, occurs along the sawtooth crack margins, which produces a highly localized stress concentration to initiate new subcrack systems. The presence of the bubbles at the crack tip during fluid pressure perturbation can enhance crack propagation.https://doi.org/10.1029/2020EA001333crackbubble nucleationcavitationcrack dynamics
collection DOAJ
language English
format Article
sources DOAJ
author Haitao Cao
Ezequiel F. Medici
Gregory P. Waite
Roohollah Askari
spellingShingle Haitao Cao
Ezequiel F. Medici
Gregory P. Waite
Roohollah Askari
Effect of Geometry and Fluid Viscosity on Dynamics of Fluid‐Filled Cracks: Insights From Analog Experimental Observations
Earth and Space Science
crack
bubble nucleation
cavitation
crack dynamics
author_facet Haitao Cao
Ezequiel F. Medici
Gregory P. Waite
Roohollah Askari
author_sort Haitao Cao
title Effect of Geometry and Fluid Viscosity on Dynamics of Fluid‐Filled Cracks: Insights From Analog Experimental Observations
title_short Effect of Geometry and Fluid Viscosity on Dynamics of Fluid‐Filled Cracks: Insights From Analog Experimental Observations
title_full Effect of Geometry and Fluid Viscosity on Dynamics of Fluid‐Filled Cracks: Insights From Analog Experimental Observations
title_fullStr Effect of Geometry and Fluid Viscosity on Dynamics of Fluid‐Filled Cracks: Insights From Analog Experimental Observations
title_full_unstemmed Effect of Geometry and Fluid Viscosity on Dynamics of Fluid‐Filled Cracks: Insights From Analog Experimental Observations
title_sort effect of geometry and fluid viscosity on dynamics of fluid‐filled cracks: insights from analog experimental observations
publisher American Geophysical Union (AGU)
series Earth and Space Science
issn 2333-5084
publishDate 2020-11-01
description Abstract Fluid‐filled volumes in geological systems can change the local stress field in the host rock and may induce brittle deformation as well as crack propagation. Although the mechanisms relating fluid pressure perturbations and seismicity have been widely studied, the fluid‐solid interaction inside the crack of a host rock is still not well understood. An analog experimental model of fluid intrusion in cracks between planar layers has been developed to study stress conditions at the margins and tips. A combined high‐speed shadowgraph and a photoelasticity imaging system is used to visualize the fluid dynamics and induced stresses on the solid matrix. Cavitation, as well as bubble growth and collapse, occurs along the sawtooth crack margins, which produces a highly localized stress concentration to initiate new subcrack systems. The presence of the bubbles at the crack tip during fluid pressure perturbation can enhance crack propagation.
topic crack
bubble nucleation
cavitation
crack dynamics
url https://doi.org/10.1029/2020EA001333
work_keys_str_mv AT haitaocao effectofgeometryandfluidviscosityondynamicsoffluidfilledcracksinsightsfromanalogexperimentalobservations
AT ezequielfmedici effectofgeometryandfluidviscosityondynamicsoffluidfilledcracksinsightsfromanalogexperimentalobservations
AT gregorypwaite effectofgeometryandfluidviscosityondynamicsoffluidfilledcracksinsightsfromanalogexperimentalobservations
AT roohollahaskari effectofgeometryandfluidviscosityondynamicsoffluidfilledcracksinsightsfromanalogexperimentalobservations
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