Helium release during shale deformation: Experimental validation

Bauer, Stephen J.; Gardner, W. Payton; Heath, Jason E.

doi:10.1002/2016gc006352

Cited by 13 publications

(32 citation statements)

References 21 publications

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“…The remaining matrix volume, modified to a lesser extent by dilation and damage, then controls the late‐time, postfailure gas release. Examination of cores after the experiment did show the existence of smaller fractures intersecting large failure planes in both experiments, which lends qualitative support to this hypothesis (Bauer, Gardner, & Heath, ).…”

Section: Discussionsupporting

confidence: 71%

“…In this simulation, we increase matrix porosity linearly from 3% to 7% during the prefailure dilation period, with a subsequent jump to 9% at the time of macroscopic failure. These changes in volume are larger than the total volume strain or dilation observed (Bauer, Gardner, & Heath, ); thus, the increase in matrix porosity results from increasing effective porosity due to damage. We have no other estimates of the increase in effective porosity other than the late‐time gas release signal.…”

Section: Resultsmentioning

confidence: 88%

“…Radon emanation decreases during early elastic deformation as porosity is decreased during compaction, begins to increase at about one third of the elastic yield stress due to the production of microfractures, and remains permanently higher after failure (Holub & Brady, 1981;Mollo et al, 2011;Nicolas et al, 2014;Tuccimei et al, 2010). Bauer, Gardner, and Lee (2016) and Bauer, Gardner, and Heath (2016) show that accumulated helium in porespace and mineral grains is also liberated during deformation. Radiogenic helium follows a repeatable sequence during deformation similar to radon, with decreasing helium flow rate during early compaction, increase in helium flow rate at about one third of the yield strength, a sharp increase during macroscopic failure, and a subsequent long-term decline in gas flow.…”

Section: Introductionmentioning

confidence: 99%

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Modeling Dynamic Helium Release as a Tracer of Rock Deformation

et al. 2017

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We use helium released during mechanical deformation of shales as a signal to explore the effects of deformation and failure on material transport properties. A dynamic dual-permeability model with evolving pore and fracture networks is used to simulate gases released from shale during deformation and failure. Changes in material properties required to reproduce experimentally observed gas signals are explored. We model two different experiments of $^4$He flow rate measured from shale undergoing mechanical deformation, a core parallel to bedding and a core perpendicular to bedding. We find that the helium signal is sensitive to fracture development and evolution as well as changes in the matrix transport properties. We constrain the timing and effective fracture aperture, as well as the increase in matrix porosity and permeability. Increases in matrix permeability are required to explain gas flow prior to macroscopic failure, and the short-term gas flow post failure. Increased matrix porosity, is required to match the long-term, post-failure gas flow. Our model provides the first quantitative interpretation of helium release as a result of mechanical deformation. The sensitivity of this model to changes in the fracture network, as well as to matrix properties during deformation, indicates that helium release can be used as a quantitative tool to evaluate the state of stress and strain in earth materials.Comment: 8 figure

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Section: Discussionsupporting

confidence: 71%

Section: Resultsmentioning

confidence: 88%

Section: Introductionmentioning

confidence: 99%

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Modeling Dynamic Helium Release as a Tracer of Rock Deformation

et al. 2017

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“…Transport of gases occurs within the rock grain, along grain boundaries, in the pore fluid, and within the micro-to macrofracture network. Their release during natural and manmade stress and strain changes represents a signal of deformation (e.g., [2][3][4][5][6]).…”

Section: Introductionmentioning

confidence: 99%

“…Noble gas emission and its relationship to crustal processes have been studied for many years in the geologic community including correlations to tectonic velocities [7], origin of crustal fluids [8], qualitative estimates of deep permeability from surface measurements [7,9], study of hydrothermal systems (e.g., [10]), and fingerprints of nuclear weapon detonation [11]. Increases in radiogenic gas at lab and field scales have been observed and related to preseismic stress, dilatancy, and/or fracturing of the rock and as potential precursory signals to earthquakes attributed to gas release due to preseismic stress [2,3,12,13]. Radon release has been observed relative to earthquake activity [14,15].…”

Section: Introductionmentioning

confidence: 99%

Noble Gas Release from Bedded Rock Salt during Deformation

2019

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Geogenic noble gases are contained in crustal rocks at inter- and intracrystalline sites. In this study, bedded rock salt from southern New Mexico was deformed in a variety of triaxial compression states while measuring the release of naturally contained helium and argon utilizing mass spectrometry. Noble gas release is empirically correlated to volumetric strain and acoustic emissions. At low confining pressures, rock salt deforms primarily by microfracturing, rupturing crystal grains, and releasing helium and argon with a large amount of acoustic emissions, both measured real-time. At higher confining pressure, microfracturing is reduced and the rock salt is presumed to deform more by intracrystalline flow, releasing less amounts of noble gases with fewer acoustic emissions. Our work implies that geogenic gas release during deformation may provide an additional signal which contains information on the type and amount of deformation occurring in a variety of earth systems.

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Release of radiogenic noble gases as a new signal of rock deformation

Bauer

Gardner

Lee

2016

Geophysical Research Letters

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In this study we investigate the release of radiogenic noble gas isotopes during mechanical deformation. We developed an analytical system for dynamic mass spectrometry of noble gas composition and helium release rate of gas produced during mechanical deformation of rocks. Our results indicate that rocks release accumulated radiogenic helium and argon from mineral grains as they undergo deformation. We found that the release of accumulated 4He and 40Ar from rocks follows a reproducible pattern and can provide insight into the deformation process. Increased gas release can be observed before dilation, and macroscopic failure is observed during high‐pressure triaxial rock deformation experiments. Accumulated radiogenic noble gases can be released due to fracturing of mineral grains during small‐scale strain in Earth materials. Helium and argon are highly mobile, conservative species and could be used to provide information on changes in the state of stress and strain in Earth materials, and as an early warning signal of macroscopic failure. These results pave the way for the use of noble gases to trace and monitor rock deformation for earthquake prediction and a variety of other subsurface engineering projects.

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Helium release during shale deformation: Experimental validation

Cited by 13 publications

References 21 publications

Modeling Dynamic Helium Release as a Tracer of Rock Deformation

Modeling Dynamic Helium Release as a Tracer of Rock Deformation

Noble Gas Release from Bedded Rock Salt during Deformation

Release of radiogenic noble gases as a new signal of rock deformation

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