Evolution of Rift Systems and Their Fault Networks in Response to Surface Processes

Neuharth, Derek; Brune, Sascha; Wrona, Thilo; Glerum, Anne; Braun, Jean; Yuan, Xiaoping

doi:10.1029/2021tc007166

Cited by 33 publications

(20 citation statements)

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“…We do not exclude that the end of low‐angle faults activity may be related to a limit to the relationship between fault offset and serpentinization (Boddupalli et al, 2022). But in agreement with observations (Lymer et al, 2019) and numerical modelling (Neuharth et al, 2022) at the Galicia margin and at the P detachment, we suggest that low‐angle faults locked‐up when they moved further away from the locus of extension, such as illustrated in our model (Figure 6c,d).…”

Section: Discussionsupporting

confidence: 93%

“…The potential mantle temperature for the southern segments of the Porcupine Basin where the PMR developed (Figure 1a), southwest of the study area, have been suggested to range from 1290° to 1450°C (Calvès et al, 2012), which may be too hot for mantle serpentinization whose maximum temperature is debated but may be between 350°C (Bickert et al, 2020) and 600°C (Lavier & Manatschal, 2006). However, mantle temperature during rifting of the northern magma‐poor segment where the P detachment developed is not defined, and recent numerical modelling indicates that serpentinization can occur in hyper‐extended, magma‐poor rift segments with low syn‐rift sedimentation (Liu et al, 2022; Neuharth et al, 2022), such as in the study area. Serpentinization also occurs at MORs where the extensional systems mix both tectonic spreading and magmatic accretion (Escartin et al, 2017; Haughton et al, 2019; Peirce et al, 2020).…”

Section: Discussionmentioning

confidence: 92%

“…Low‐angle corrugated extensional detachments are commonly believed to represent the inactive part of a steep fault that has undergone extreme flexural back‐rotation; the inactive shallow fault maintaining continuity with the active steep fault (Buck, 1988; Choi et al, 2013; Deng et al, 2020; Escartin et al, 2017; Mizera et al, 2019; Olive et al, 2019; Reston, 2018; Smith et al, 2014; Webber et al, 2020; Ye et al, 2022). Despite the general acceptance of this model, the linkage between steep and shallow parts of detachments has never been directly observed and the back rotation of detachment faults from high to low angles has been inferred from indirect observations, including: palaeomagnetic measures of extreme footwall rotation (MacLeod et al, 2009; Morris et al, 2009), seismic imaging of shallow detachments (Reston & Ranero, 2011), numerical simulations (Buck, 1988; Choi et al, 2013; Liu et al, 2022; Neuharth et al, 2022) and P‐wave velocity models associated with microseismicity monitoring at MOR detachments (deMartin et al, 2007; Parnell‐Turner et al, 2020). For instance, microearthquake data from two oceanic detachments and associated corrugated low‐angle domes at 13°20′N and 13°30′N along the Mid‐Atlantic Ridge (MAR), show a band of seismicity dipping at ca.…”

Section: Introductionmentioning

confidence: 99%

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Punctuated propagation of a corrugated extensional detachment offshore Ireland

2022

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Low‐angle detachments are fundamental crustal structures found in many extensional systems and plate tectonic boundaries, including onshore extensional basins, rifted margins and mid‐oceanic ridges. Direct observations of the complete geometry of extensional detachments are rare so that aspects of our understanding of their development and evolution rely mainly on proxy observations and numerical simulations. A high‐resolution 3D seismic reflection survey Offshore West of Ireland images a complete corrugated extensional detachment, from its steep oceanward breakaway faults to its back‐rotated domal crest. The detachment surface, the P reflector, developed during the Jurassic hyperextension of the Porcupine Basin and is preserved in its slip position. It covers 95 × 35 km area and has a N‐S elongate domal shape, at right angles to the prevailing extension direction, with a crest at ca. 6.3 s two‐way travel time. It is overlain by a syn‐rift sequence offset by steep frontal faults that pass eastward into shallower, predominantly west‐dipping highly listric faults that merge downwards with the detachment. The detachment has pronounced E‐W corrugations parallel to the basin opening direction, and N‐S lineaments that correspond with the footwall cutoff lines of overlying Jurassic faults. The most significant N‐S lineaments correspond with changes in dip of the detachment. We propose that the geometry of P can be explained by a conceptual model in which the detachment was assembled from initially steep faults that developed at the front of P and back‐rotated to form listric faults during extension, with punctuated oceanward propagation of the segments of the detachment. Comparisons with 2D profiles and 3D surfaces of published detachments suggest that our conceptual model may be applicable to other detachments that accommodate extreme extension at other rifted margins and at mid‐oceanic slow and ultra‐slow spreading ridges.

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Section: Discussionsupporting

confidence: 93%

Section: Discussionmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 99%

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Punctuated propagation of a corrugated extensional detachment offshore Ireland

2022

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“…We acknowledge that the approach presented in Reeve et al ( 2022) may have been driven by mathematical models suggesting regional stratigraphic unconformities as representative of the geodynamic processes causing continental breakup. There are several examples of these models in the recent literature (Korchinski et al, 2021;Neuharth et al, 2022;Pérez-Gussinyé et al, 2020). Such models are often formulated assuming sedimentation rates that are relatively constant across and along continental margins, and sediment sources that are homogeneous in nature.…”

Section: Discussionmentioning

confidence: 99%

Stratigraphic record of continental breakup, offshore NW Australia—Discussion

et al. 2022

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Reeve et al. (2022) address the stratigraphic record of continental breakup by focusing on a set of stratigraphic unconformities from a proxima l sector of the NW Australian continenta l margin, inboard from the Exmouth Plateau. They suggest that such unconfor mities can potentially document a well-defined three-stage process: end of the synrift phase, formatio n of a wide continent-ocea n transitio n zone (COTZ) and generatio n of 'true' Penrose-type oceanic crust. We counterargue that continental breakup is a protracted event that can only be understood via seismic-and chronostratigraphic correlations of strata, and their composing sequences, across and along rifted margins. Tying proxima l stratigraphic unconfor mities to magnetic anomalies outboard from the study area in Reeve et al. ( 2022) is This article has been accepted for publication and undergone full peer review but has not been through the copyediting, typesetting, pagination and proofreading process which may lead to differences between this version and the Version of Record. Please cite this article as

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“…Additionally, the current version incorporates surface processes, imposing rates of erosion and sedimentation on the top of the free surface (Silva & Sacek, 2022). Recently, other thermomechanical codes available for the scientific community incorporated the interaction with surface processes (e.g., Beucher & Huismans, 2020;Neuharth et al, 2022) taking into account the simulation of fluvial and hillslope processes. In the present version of Mandyoc, only predefined erosion/sedimentation rate (variable in space and time) is possible.…”

Section: Statement Of Needmentioning

confidence: 99%

Mandyoc: A finite element code to simulate thermochemical convection in parallel

Sacek¹,

Assunção²,

Pesce³

et al. 2022

JOSS

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Mandyoc is a 2-D finite element code written in C dedicated to simulating thermochemical convection in the interior of terrestrial planets. Different linear and non-linear rheologies can be adopted, appropriately simulating the strain and stress pattern in the Earth's crust and mantle, both in extensional and collisional tectonics. Additionally, the code allows variations of boundary condition for the velocity field in space and time, simulating different pulses of tectonism in the same numerical scenario.

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Evolution of Rift Systems and Their Fault Networks in Response to Surface Processes

Cited by 33 publications

References 100 publications

Punctuated propagation of a corrugated extensional detachment offshore Ireland

Punctuated propagation of a corrugated extensional detachment offshore Ireland

Stratigraphic record of continental breakup, offshore NW Australia—Discussion

Mandyoc: A finite element code to simulate thermochemical convection in parallel

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