Zoe K. Shipton scite author profile

Deformation bands are the most common strain localization feature found in deformed porous sandstones and sediments, including Quaternary deposits, soft gravity slides and tectonically affected sandstones in hydrocarbon reservoirs and aquifers. They occur as various types of tabular deformation zones where grain reorganization occurs by grain sliding, rotation and/or fracture during overall dilation, shearing, and/or compaction. Deformation bands with a component of shear are most common and typically accommodate shear offsets of millimetres to centimetres. They can occur as single structures or cluster zones, and are the main deformation element of fault damage zones in porous rocks. Factors such as porosity, mineralogy, grain size and shape, lithification, state of stress and burial depth control the type of deformation band formed. Of the different types, phyllosilicate bands and most notably cataclastic deformation bands show the largest reduction in permeability, and thus have the greatest potential to influence fluid flow. Disaggregation bands, where non-cataclastic, granular flow is the dominant mechanism, show little influence on fluid flow unless assisted by chemical compaction or cementation.

show abstract

Damage zone and slip-surface evolution over μm to km scales in high-porosity Navajo sandstone, Utah

Shipton

Cowie

2001

Journal of Structural Geology

377

194

View full text Add to dashboard Cite

What do you think this is? “Conceptual uncertainty” in geoscience interpretation

et al. 2007

View full text Add to dashboard Cite

Interpretations of seismic images are used to analyze subsurface geology and form the basis for many exploration and extraction decisions, but the uncertainty that arises from human bias in seismic data interpretation has not previously been quantified. All geological data sets are spatially limited and have limited resolution. Geoscientists who interpret such data sets must, therefore, rely upon their previous experience and apply a limited set of geological concepts. We have documented the range of interpretations to a single data set, and in doing so have quantified the "conceptual uncertainty" inherent in seismic interpretation. In this experiment, 412 interpretations of a synthetic seismic image were analyzed. Only 21% of the participants interpreted the "correct" tectonic setting of the original model, and only 23% highlighted the three main fault strands in the image. These results illustrate that conceptual uncertainty exists, which in turn explains the large range of interpretations that can result from a single data set. We consider the role of prior knowledge in biasing individuals in their interpretation of the synthetic seismic section, and our results demonstrate that conceptual uncertainty has a critical influence on resource exploration and other areas of geoscience. Practices should be developed to minimize the effects of conceptual uncertainty, and it should be accounted for in risk analysis.

show abstract

Analysis of CO ₂ leakage through ‘low-permeability’ faults from natural reservoirs in the Colorado Plateau, east-central Utah

et al. 2004

View full text Add to dashboard Cite

The numerous CO2 reservoirs in the Colorado Plateau region of the United States are natural analogues for potential geological CO2 sequestration repositories. To understand better the risk of leakage from reservoirs used for long-term underground CO2 storage, we examine evidence for CO2 migration along two normal faults that cut a reservoir in east-central Utah. CO2-charged springs, geysers, and a hydrocarbon seep are localized along these faults. These include natural springs that have been active for long periods of time, and springs that were induced by recent drilling. The CO2-charged spring waters have deposited travertine mounds and carbonate veins. The faults cut siltstones, shales, and sandstones and the fault rocks are fine-grained, clay-rich gouge, generally thought to be barriers to fluid flow. The geological and geochemical data are consistent with these faults being conduits for CO2 moving to the surface. Consequently, the injection of CO2 into faulted geological reservoirs, including faults with clay gouge, must be carefully designed and monitored to avoid slow seepage or fast rupture to the biosphere.

show abstract

Pulses of carbon dioxide emissions from intracrustal faults following climatic warming

et al. 2012

View full text Add to dashboard Cite

Carbon capture and geological storage represents a potential means of managing atmospheric carbon dioxide levels. Understanding the role of faults, as either barriers or conduits to the flow of carbon dioxide, is crucial for predicting the long-term integrity of geological storage sites. Of particular concern is the influence of geochemical reactions on the sealing behaviour of faults and the impact of seismicity and stress regime on fault stability. Here, we examine a 135,000-year palaeorecord of carbon dioxide leakage from a faulted, natural carbon dioxide reservoir in Utah. We assess the isotope and trace-element composition of U-Th-dated carbonate veins, deposited by carbon-dioxide-rich fluids. Temporal changes in vein geochemistry reveal pulses of carbon dioxide injection into the reservoir from deeper formations. Surface leakage rates increase by several orders of magnitude following these pulses. We show that each pulse occurs around 100-2,000 years after the onset of significant local climatic warming, at glacial to interglacial transitions. We suggest that carbon dioxide leakage rates increase as a result of fracture opening, potentially caused by changes in groundwater hydrology, the intermittent presence of a buoyant gas cap and postglacial crustal unloading of regions surrounding the fault

show abstract

Fault tip displacement gradients and process zone dimensions

Cowie

Shipton

1998

Journal of Structural Geology

217

102

View full text Add to dashboard Cite

A conceptual model for the origin of fault damage zone structures in high-porosity sandstone

Shipton¹,

Cowie²

2003

Journal of Structural Geology

265

View full text Add to dashboard Cite

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

hi@scite.ai

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Zoe K. Shipton

A review of recent developments concerning the structure, mechanics and fluid flow properties of fault zones

Deformation bands in sandstone: a review

Damage zone and slip-surface evolution over μm to km scales in high-porosity Navajo sandstone, Utah

What do you think this is? “Conceptual uncertainty” in geoscience interpretation

Analysis of CO ₂ leakage through ‘low-permeability’ faults from natural reservoirs in the Colorado Plateau, east-central Utah

Pulses of carbon dioxide emissions from intracrustal faults following climatic warming

Fault tip displacement gradients and process zone dimensions

A conceptual model for the origin of fault damage zone structures in high-porosity sandstone

Contact Info

Product

Resources

About

Zoe K. Shipton

A review of recent developments concerning the structure, mechanics and fluid flow properties of fault zones

Deformation bands in sandstone: a review

Damage zone and slip-surface evolution over μm to km scales in high-porosity Navajo sandstone, Utah

What do you think this is? “Conceptual uncertainty” in geoscience interpretation

Analysis of CO 2 leakage through ‘low-permeability’ faults from natural reservoirs in the Colorado Plateau, east-central Utah

Pulses of carbon dioxide emissions from intracrustal faults following climatic warming

Fault tip displacement gradients and process zone dimensions

A conceptual model for the origin of fault damage zone structures in high-porosity sandstone

Contact Info

Product

Resources

About

Analysis of CO ₂ leakage through ‘low-permeability’ faults from natural reservoirs in the Colorado Plateau, east-central Utah