Fault architecture and deformation processes within poorly lithified rift sediments, Central Greece

Loveless, Sian; Bense, Victor; Turner, Jenni

doi:10.1016/j.jsg.2011.09.008

Cited by 44 publications

(18 citation statements)

References 56 publications

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“…A foliated-clay structure developed in most of the clay-rich fault core. Loveless et al, 2011) have noted the presence of mixed zones along faults in poorly consolidated sediments. These studies are in poorly consolidated siliciclastic units with grain size ranging from gravel to clay that underwent deformation through particulate flow at less than 1 km depth.…”

Section: Fault Growth and Clay Smearingmentioning

confidence: 99%

“…Heynekamp et al (1999); Sigda et al (1999); Rawling et al (2001) and Rawling and Goodwin (2003) defined the mixed zone as being located between the fault core and the damage zone rather than being the fault core. Loveless et al (2011) considers the mixed zone as representing the fault core based on hydrological behaviour. Due to this ambiguity in the meaning of the term mixed zone, we prefer to use the term breccia as a geometrical description of the sandy pods texture.…”

Section: Fault Growth and Clay Smearingmentioning

confidence: 99%

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Along-strike fault core thickness variations of a fault in poorly lithified sediments, Miri (Malaysia)

Rosa

Shipton

Lunn

et al. 2018

Journal of Structural Geology

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This version is available at https://strathprints.strath.ac.uk/65335/ Strathprints is designed to allow users to access the research output of the University of Strathclyde. Unless otherwise explicitly stated on the manuscript, Copyright © and Moral Rights for the papers on this site are retained by the individual authors and/or other copyright owners. Please check the manuscript for details of any other licences that may have been applied. You may not engage in further distribution of the material for any profitmaking activities or any commercial gain. You may freely distribute both the url (https://strathprints.strath.ac.uk/) and the content of this paper for research or private study, educational, or not-for-profit purposes without prior permission or charge.Any correspondence concerning this service should be sent to the Strathprints administrator: strathprints@strath.ac.ukThe Strathprints institutional repository (https://strathprints.strath.ac.uk) is a digital archive of University of Strathclyde research outputs. It has been developed to disseminate open access research outputs, expose data about those outputs, and enable the management and persistent access to Strathclyde's intellectual output. The degree to which a fault will impede fluid flow is only as great as its most permeable point. Processes that determine areas of the fault surface containing transmissible fault rocks must be utilized to produce reliable predictions of cross-fault fluid flow. We use a study site in Miri, Malaysia, to investigate in detail the fault-core thickness variations along-strike and down dip, and to quantify the risk of discontinuities in the clay-rich fault core. Four fault-core types have been identified: foliated clay-rich fault core, chaotic clay-rich fault core, anastomosing sandy shear zones and sandy breccia. We performed a geostatistical analysis, showing a correlation over 3 m scale, suggesting the presence of 'patches' of thin and thick fault core generally less than 3 m in length in profile.We interpret this geometry as superimposition of two or more different deformation processes at a smaller and a larger scale. We speculate about the processes that could produce the observed distribution of thickness and composition, and in particular, processes that could have disrupted the through-going clay-rich core.

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Section: Fault Growth and Clay Smearingmentioning

confidence: 99%

Section: Fault Growth and Clay Smearingmentioning

confidence: 99%

Along-strike fault core thickness variations of a fault in poorly lithified sediments, Miri (Malaysia)

Rosa

Shipton

Lunn

et al. 2018

Journal of Structural Geology

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“…Increased tortuosity between holes further reduces fluid flux across the fault, but this flux is still greater than that across a thin clay smear. Sand smears separating two or more parallel clay smears in a single fault are described by several authors [ Loveless et al ., ; Bastesen et al ., ; Bense et al ., ; Kristensen et al ., ; Kettermann et al ., ], but confident observation of permeable connectivity across the fault is difficult in a field setting.…”

Section: Discussionmentioning

confidence: 98%

“…Outcrop studies provide high‐resolution data of clay smear structures and processes in a wide range of spatial scales and lithification states [ Weber et al ., ; Lindsay et al ., ; Lehner and Pilaar , ; Foxford et al ., ; Heynekamp et al ., ; Aydin and Eyal , ; Bense et al ., ; van der Zee et al ., ; Clausen et al ., ; Doughty , ; van der Zee and Urai , ; Davatzes and Aydin , ; Eichhubl et al ., ; Faerseth , ; Loveless et al ., ; Kristensen et al ., ; Kettermann et al ., ]. The inherent 3‐D variability of clay smears is recognized as difficult to explore in two‐dimensional outcrop studies [ Foxford et al ., ; Vrolijk et al ., ].…”

Section: Introductionmentioning

confidence: 99%

Evolution of structure and permeability of normal faults with clay smear: Insights from water‐saturated sandbox models and numerical simulations

2017

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Clay smear is difficult to predict for subsurface flow applications and would benefit from an improved understanding of the processes controlling clay smear. We present water‐saturated sandbox experiments with large clay smear surfaces (~500 cm2) that couple cross‐fault fluid flow measurements with structural analysis of excavated clay smears. We compare measured flow data to numerical flow simulations to develop a tool to evaluate the evolving fault structure. Results show diagnostic relationships between fault structures and cross‐fault flow. In experiments with one or two clay layers and a cumulative thickness of 10 mm at 100 mm displacement, normally consolidated clay in a structural domain of graben faulting initially yields hybrid brittle/ductile failure with early breaching of the clay layer and increased cross‐fault flux. This is followed by fault backstepping, formation of clay smears, and reworking of clay fragments within the fault. Early formed holes remain open during the evolution of the faults. Fault zones are segmented by fault lenses, breached relays, and clay smears in which sand and clay mix by deformation. Experiments with two clay layers show that holes rarely form at the same position on the fault plane, producing a layered sand‐clay fault rock with greater flow path tortuosity and lower permeability than in one‐layer experiments. We compare our results with observations of faults in nature and discuss progress toward models with sufficient detail and understanding to allow prediction of flow across evolving faults, first in laboratory models and then in the subsurface.

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“…In regard to a 559 mechanically layered sequence of beds, the resultant distribution of faults or joints 560 has higher complexity (e.g., Welch et al, 2009b). The detailed outcrop studies also 561 suggested that stratigraphy plays an important role in determining the detailed fault 562 architecture at meso-scale and micro-scale (e.g., Loveless et al, 2011;Pei et al, 563 2015). Many mechanical and physical models suggested the important role of 564 stratigraphy and its strength in controlling the deformation style; however, it is likely 565 to be second-order controls superimposed upon the first-order geometry that are 566 dominated by the throw distribution along a thrust fault (Allmendinger, 1998;Dixon, 567 2004;Pei et al, 2014;Welch et al, 2009a).…”

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confidence: 99%

Examining fault architecture and strain distribution using geospatial and geomechanical modelling: An example from the Qaidam basin, NE Tibet

Pei

Paton

Knipe

et al. 2017

Marine and Petroleum Geology

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7The investigation of complex geological setting is still dominated by traditional geo-8 data collection and analytical techniques, e.g., stratigraphic logging, dip data 9 measurements, structural ground mapping, seismic interpretation, balance section 10 restoration, forward modelling, etc. Despite the advantages of improving our 11 understanding in structural geometry and fault architecture, the geospatial modelling, 12 applying computer-aided three-dimensional geometric design, visualization and 13 interpretation, has rarely been applied to such complex geological setting. This study 14 used the Lenghu fold-and-thrust belt (in Qaidam basin, NE Tibetan Plateau) to 15 demonstrate that the application of geospatial and geomechanical modelling could 16 improve our understanding and provide an effective technique for investigating the 17 fault architecture and strain distribution. The three-dimensional configuration of the 18Lenghu fold-and-thrust belt was initially derived from traditional analysis techniques, 19 such as regional stratigraphic logging, cross section construction, meso-scale ground 20 mapping and landsat image interpretation. The high-resolution field data and landsat 21 image were integrated to construct the geospatial model, which was subsequently 22 used to quantitatively investigate the fault throw changes along the Lenghu thrust 23 fault zone and to understand its control on the lateral structural variation. The 24 geospatial model was then restored in three dimensions to reveal the kinematic 25 evolution of the Lenghu fold-and-thrust belt. Geomechanical modelling, using a 26 M A N U S C R I P T A C C E P T E D ACCEPTED MANUSCRIPT2 Mass-Spring algorithm, provided an effective three-dimensional tool for structural 27 strain analysis, which was used to predict the strain distribution throughout the 28 overall structure, e.g., normal faults with throws ranging from meters to tens of 29 meters in the hanging-wall. The strain distribution predicted by geomechanical 30 modelling was then validated by the natural normal faults in the hanging-wall. The 31 high accordance between the strain prediction and statistics of natural normal faults 32 demonstrates good applicability of geospatial and geomechanical modelling in the 33 complex geological setting of the Lenghu fold-and-thrust belt. The geospatial models 34 and geomechanical models, therefore, can provide a robust technique for analyzing 35 and interpreting multi-source data within a three-dimensional environment. We 36 anticipate that the application of three-dimensional geospatial modelling and 37 geomechanical modelling, integrating both multi-source geologic data and three-38 dimensional analytical techniques, can provide an effective workflow for investigating 39 the fault architecture and strain distribution at different scales (e.g., ranging from 40 regional-to meso-scale). 41Keywords 42 geospatial modelling, geomechanical modelling, fault architecture, strain distribution 43 prediction 44

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Fault architecture and deformation processes within poorly lithified rift sediments, Central Greece

Cited by 44 publications

References 56 publications

Along-strike fault core thickness variations of a fault in poorly lithified sediments, Miri (Malaysia)

Along-strike fault core thickness variations of a fault in poorly lithified sediments, Miri (Malaysia)

Evolution of structure and permeability of normal faults with clay smear: Insights from water‐saturated sandbox models and numerical simulations

Examining fault architecture and strain distribution using geospatial and geomechanical modelling: An example from the Qaidam basin, NE Tibet

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