How displacement analysis may aid fault risking strategies for CO<sub>2</sub> storage

Michie, Emma A. H.; Braathen, Alvar

doi:10.1111/bre.12807

Cited by 3 publications

(1 citation statement)

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“…The value of considering the fault growth history in assessing the potential of faults to seal or leak fluids has recently received increased interest (e.g., Reilly et al, 2017;Song et al, 2020;Michie & Braathen, 2023). While assessing present-day juxtaposition relationships and fault sealing potential is a valuable approach when considering reservoir behaviour over relatively short (i.e., a few tens of years) production timescales, it does not capture the changes that may occur to fault hydraulic properties over longer, geological timescales (e.g., Manzocchi et al, 2010;Reilly et al, 2017).…”

Section: Fault Network Kinematics and Sealing Potentialmentioning

confidence: 99%

The Role of Normal Fault Growth History in Influencing Fault Seal Potential, Samson Dome, Offshore Norway

Alghuraybi,

Bell,

Jackson

2023

Preprint

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The growth of normal faults can influence subsurface fluid flow and entrapment within rift basins. However, fault seal studies typically view faults as static structures, with their growth and the potential related temporal changes in hydraulic properties being ignored. In this study, we use borehole data and a high-quality 3D full-stack depth migrated seismic reflection volume to analyse the growth history of the normal fault network in the Samson Dome area, SW Barents Sea. We specifically focus on how the kinematic history of normal faults impacts their sealing properties, whilst also considering their origin and implications for regional salt tectonics. We show that the faults formed during two distinct phases in the Late Triassic and Middle Jurassic-to-Early Cretaceous, and two phases of dome growth occurred in the Late Triassic and Late Cretaceous, challenging existing proposals for the timing of the development of structure. The salt-tectonic origin of the Samson Dome itself remains enigmatic, although mechanical considerations suggest existing models require refinement. Our fault seal analysis reveals a correlation between displacement patterns and sealing potential, as reflected in the Shale Gouge Ratio (SGR) values of different fault groups. More specifically, faults that grew via vertical linkage of initially isolated segments and experienced potential reactivation exhibit lower SGR values, implying a higher likelihood of across and along-fault leakage. Conversely, faults lacking evidence for reactivation or vertical linkage show higher SGR values, suggesting better sealing potential. Notably, the accuracy of our fault seal analysis is greatly influenced by the calculation methods used for Vshale, particularly for faults with low displacement. Our study provides valuable insights into the faulting, development, and sealing potential of the Samson Dome area. We also highlight the importance of careful consideration of Vshale calculation methods when conducting fault seal analysis.

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Section: Fault Network Kinematics and Sealing Potentialmentioning

confidence: 99%

The Role of Normal Fault Growth History in Influencing Fault Seal Potential, Samson Dome, Offshore Norway

Alghuraybi,

Bell,

Jackson

2023

Preprint

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Implications of depth conversion on fault geometries and fault-risk assessment in the Smeaheia CO ₂ storage site, northern North Sea

Holden,

Alaei,

Skurtveit

et al. 2024

Geoenergy

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Assessments of fault geometries and fault-risk parameters are crucial when evaluating the integrity of a structurally controlled CO 2 storage site. To perform these assessments, seismic data, recorded in time, must be converted to depth. The velocity models used for this time-depth conversion influence the final depth image and, consequently, the geometry of the interpreted faults. Against this background, we create four velocity models for depth conversion, assess the impact on fault throw, dip, and thickness of the primary seal, and, subsequently, fault-risk assessment of the Vette Fault Zone in the Smeaheia CO 2 storage site. We find that fault throw and thickness of the primary seal are more influenced by depth conversion compared to fault dip. In contrast, the overall assessment of membrane seal presence and geomechanical integrity shows less sensitivity to the depth conversion process. Consequently, we suggest that a relatively robust fault-risk assessment can be made with a variety of velocity model designs and data input. Nevertheless, we find a mean difference of 2% shale gouge ratio, 4% slip tendency, and 9% dilation tendency for the Vette Fault Zone emphasizing the importance of accounting for the influence of depth conversion to optimize structural assessments in potential CO 2 storage sites.

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Optimizing Fault Risking Strategies for Subsurface Resource Exploration on the Exmouth Plateau, NW Australia

Bankole,

Omosanya,

Adebisi

et al. 2024

SPE Nigeria Annual International Conference and Exhibition

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The understanding of geological fault growth history is critical in subsurface resource exploration, given the key role faults play in maintaining reservoir integrity. Traditional practices involve assessing fault initiation, propagation, segmentation, linkage, and reactivation to elucidate their growth mechanisms and history. Various traditional methods, complemented by fault growth models, are employed, with the choice of method contingent on the study's scope and objectives. In this study, we use high-quality, high-resolution three-dimensional (3D) seismic reflection data to investigate the evolution of two primary faults intersecting the Exmouth Plateau, offshore Northwest Australia. By applying displacement analysis techniques, including variations of fault displacement/throw with distance (T-x), throw (T) with depth (T-z), and Allan diagrams, we scrutinize potential leaking or compromised segments along the interpreted faults. Our results show that the faults are oriented in the NNE-SSW direction and developed under extensional regimes from the Middle Triassic to Late Jurassic. These faults show high segmentation along strike and mild segmentation along dip. Their T-x profiles reveal a multiple-segment profile of C-type and hybrid C-type, indicating evolution from the linkage of different fault segments at local displacement minima. Importantly, the Allan diagram highlights a leakage zone along F1 at the Top Rankin Beds unit, where a throw of less than 10 ms (approximately 10 m) was recorded. This area represents a potential site of subsurface fluid leakage, including oil, CO2, hydrogen, and other gases. The techniques and results presented here have profound implications for subsurface resource exploration in the studied area, with broader applications in similar settings worldwide.

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How displacement analysis may aid fault risking strategies for CO₂ storage

Cited by 3 publications

References 106 publications

The Role of Normal Fault Growth History in Influencing Fault Seal Potential, Samson Dome, Offshore Norway

The Role of Normal Fault Growth History in Influencing Fault Seal Potential, Samson Dome, Offshore Norway

Implications of depth conversion on fault geometries and fault-risk assessment in the Smeaheia CO ₂ storage site, northern North Sea

Optimizing Fault Risking Strategies for Subsurface Resource Exploration on the Exmouth Plateau, NW Australia

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How displacement analysis may aid fault risking strategies for CO2 storage

Cited by 3 publications

References 106 publications

The Role of Normal Fault Growth History in Influencing Fault Seal Potential, Samson Dome, Offshore Norway

The Role of Normal Fault Growth History in Influencing Fault Seal Potential, Samson Dome, Offshore Norway

Implications of depth conversion on fault geometries and fault-risk assessment in the Smeaheia CO 2 storage site, northern North Sea

Optimizing Fault Risking Strategies for Subsurface Resource Exploration on the Exmouth Plateau, NW Australia

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How displacement analysis may aid fault risking strategies for CO₂ storage

Implications of depth conversion on fault geometries and fault-risk assessment in the Smeaheia CO ₂ storage site, northern North Sea