The structural evolution of pull-apart basins in response to changes in plate motion

G.-P. Farangitakis; K.J.W. McCaffrey; E. Willingshofer; M.B. Allen; L.M. Kalnins; J. van Hunen; P. Persaud; D. Sokoutis

doi:10.1111/bre.12528

The structural evolution of pull-apart basins in response to changes in plate motion

G.-P. Farangitakis, K.J.W. McCaffrey, E. Willingshofer, M.B. Allen, L.M. Kalnins, J. van Hunen, P. Persaud, D. Sokoutis

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Pull-apart basins are structural features linked to the interactions between strike-slip and extensional tectonics. Their morphology and structural evolution are determined by factors such as extension rate, the basin length/width ratio, and changes in extension direction. In this work, we investigate the effect of a change in the plate motion direction on a pull-apart basin's structure, using analogue modelling experiments with a two-layer ductile-brittle configuration to simulate continental crust rheology. We initially impose orthogonal extension on an interconnected rift and strike-slip system to drive pull-apart development. Subsequently, we rotate the relative motion vector, imposing transtensional deformation and continuing with this new relative motion vector to the end of the experiment. To compare with natural examples, we analyse the model using seismic interpretation software, generating 3D fault structure and sedimentary thickness interpretations. Results show that the change in the direction of plate motion produces map-view sigmoidal oblique slip faults that become normal-slip when deformation adjusts to the new plate motion vector. Furthermore, sediment distribution is strongly influenced by the relative plate rotation, changing the locus of deposition inside the basin at each model stage. Finally, we compare our observations to seismic reflection images, sedimentary package thicknesses and fault interpretations from the Northern Gulf of California and find good agreement between model and nature. Similar fault arrays occur in the Bohai Basin in northern China, which suggests a rotational component in its evolution. More broadly, such similar structures could indicate a role for oblique extension and fault rotation in any pull-apart basin.

Original language	English
Pages (from-to)	1603-1625
Number of pages	23
Journal	Basin Research
Volume	33
Issue number	2
DOIs	https://doi.org/10.1111/bre.12528
Publication status	Published - Apr 2021

Bibliographical note

Funding Information:
The work contained in this paper contains work conducted during a PhD study undertaken as part of the Natural Environment Research Council (NERC) Centre for Doctoral Training (CDT) in Oil & Gas [grant number NEM00578X/1]. It is co‐sponsored by Durham University, whose support is gratefully acknowledged. LMK is supported by a Royal Society of Edinburgh Personal Research Fellowship funded by the Scottish Government. The authors thank the Editor‐in‐Chief of Basin Research, Atle Rotevatn, and the three reviewers, Chris Morley, Hanna M Elston and Alexander Cruden, for their constructive comments which helped improve this manuscript.

Publisher Copyright:
© 2020 The Authors. Basin Research published by International Association of Sedimentologists and European Association of Geoscientists and Engineers and John Wiley & Sons Ltd

Keywords

extension
plate motion changes
pull-apart basins
strike-slip
transtension

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https://www.scopus.com/inward/record.uri?eid=2-s2.0-85100153673&doi=10.1111%2fbre.12528&partnerID=40&md5=c5cbb18ce79421dd952f9d2881dc5189

Cite this

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title = "The structural evolution of pull-apart basins in response to changes in plate motion",

abstract = "Pull-apart basins are structural features linked to the interactions between strike-slip and extensional tectonics. Their morphology and structural evolution are determined by factors such as extension rate, the basin length/width ratio, and changes in extension direction. In this work, we investigate the effect of a change in the plate motion direction on a pull-apart basin's structure, using analogue modelling experiments with a two-layer ductile-brittle configuration to simulate continental crust rheology. We initially impose orthogonal extension on an interconnected rift and strike-slip system to drive pull-apart development. Subsequently, we rotate the relative motion vector, imposing transtensional deformation and continuing with this new relative motion vector to the end of the experiment. To compare with natural examples, we analyse the model using seismic interpretation software, generating 3D fault structure and sedimentary thickness interpretations. Results show that the change in the direction of plate motion produces map-view sigmoidal oblique slip faults that become normal-slip when deformation adjusts to the new plate motion vector. Furthermore, sediment distribution is strongly influenced by the relative plate rotation, changing the locus of deposition inside the basin at each model stage. Finally, we compare our observations to seismic reflection images, sedimentary package thicknesses and fault interpretations from the Northern Gulf of California and find good agreement between model and nature. Similar fault arrays occur in the Bohai Basin in northern China, which suggests a rotational component in its evolution. More broadly, such similar structures could indicate a role for oblique extension and fault rotation in any pull-apart basin.",

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author = "G.-P. Farangitakis and K.J.W. McCaffrey and E. Willingshofer and M.B. Allen and L.M. Kalnins and {van Hunen}, J. and P. Persaud and D. Sokoutis",

note = "Funding Information: The work contained in this paper contains work conducted during a PhD study undertaken as part of the Natural Environment Research Council (NERC) Centre for Doctoral Training (CDT) in Oil & Gas [grant number NEM00578X/1]. It is co‐sponsored by Durham University, whose support is gratefully acknowledged. LMK is supported by a Royal Society of Edinburgh Personal Research Fellowship funded by the Scottish Government. The authors thank the Editor‐in‐Chief of Basin Research, Atle Rotevatn, and the three reviewers, Chris Morley, Hanna M Elston and Alexander Cruden, for their constructive comments which helped improve this manuscript. Publisher Copyright: {\textcopyright} 2020 The Authors. Basin Research published by International Association of Sedimentologists and European Association of Geoscientists and Engineers and John Wiley & Sons Ltd",

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AU - Farangitakis, G.-P.

AU - McCaffrey, K.J.W.

AU - Willingshofer, E.

AU - Allen, M.B.

AU - Kalnins, L.M.

AU - van Hunen, J.

AU - Persaud, P.

AU - Sokoutis, D.

N1 - Funding Information: The work contained in this paper contains work conducted during a PhD study undertaken as part of the Natural Environment Research Council (NERC) Centre for Doctoral Training (CDT) in Oil & Gas [grant number NEM00578X/1]. It is co‐sponsored by Durham University, whose support is gratefully acknowledged. LMK is supported by a Royal Society of Edinburgh Personal Research Fellowship funded by the Scottish Government. The authors thank the Editor‐in‐Chief of Basin Research, Atle Rotevatn, and the three reviewers, Chris Morley, Hanna M Elston and Alexander Cruden, for their constructive comments which helped improve this manuscript. Publisher Copyright: © 2020 The Authors. Basin Research published by International Association of Sedimentologists and European Association of Geoscientists and Engineers and John Wiley & Sons Ltd

PY - 2021/4

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N2 - Pull-apart basins are structural features linked to the interactions between strike-slip and extensional tectonics. Their morphology and structural evolution are determined by factors such as extension rate, the basin length/width ratio, and changes in extension direction. In this work, we investigate the effect of a change in the plate motion direction on a pull-apart basin's structure, using analogue modelling experiments with a two-layer ductile-brittle configuration to simulate continental crust rheology. We initially impose orthogonal extension on an interconnected rift and strike-slip system to drive pull-apart development. Subsequently, we rotate the relative motion vector, imposing transtensional deformation and continuing with this new relative motion vector to the end of the experiment. To compare with natural examples, we analyse the model using seismic interpretation software, generating 3D fault structure and sedimentary thickness interpretations. Results show that the change in the direction of plate motion produces map-view sigmoidal oblique slip faults that become normal-slip when deformation adjusts to the new plate motion vector. Furthermore, sediment distribution is strongly influenced by the relative plate rotation, changing the locus of deposition inside the basin at each model stage. Finally, we compare our observations to seismic reflection images, sedimentary package thicknesses and fault interpretations from the Northern Gulf of California and find good agreement between model and nature. Similar fault arrays occur in the Bohai Basin in northern China, which suggests a rotational component in its evolution. More broadly, such similar structures could indicate a role for oblique extension and fault rotation in any pull-apart basin.

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KW - transtension

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EP - 1625

JO - Basin Research

JF - Basin Research

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ER -

The structural evolution of pull-apart basins in response to changes in plate motion

Abstract

Bibliographical note

Keywords

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