Strain localization at the margins of strong lithospheric domains: Insights from analog models

Calignano, Elisa; Sokoutis, Dimitrios; Willingshofer, Ernst; Gueydan, Frédéric; Cloetingh, S.A.P.L.

doi:10.1002/2014tc003756

Cited by 38 publications

(38 citation statements)

References 88 publications

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“…The mechanical properties of continental lithosphere are strongly heterogeneous in space, as documented by observations and suggested by mechanical models (Burov, 2011;Cloetingh et al, 2005;Gueydan et al, 2014;Ranalli, 1997). The reactivation of lithospheric heterogeneities controlled the evolution of intra-plate orogens in Iberia (Pyrenees, Spanish Central System, Iberian Range), Australia (Petermann and Alice Spring orogens), Central America (Laramide orogen), and Central Asia (Tian Shan) (Beaumont et al, 2000;Cerca et al, 2004;Cloetingh et al, 2005;Delvaux et al, 2013;Fernández-Lozano et al, 2011;Gorczyk et al, 2013;Kennett and Iaffaldano, 2013;Raimondo et al, 2014;Sainz and Faccenna, 2001). At lithospheric scale the nature of the reactivated heterogeneities is diverse and debated.…”

Section: Introductionmentioning

confidence: 93%

“…Previous modelling studies focused on initiation of intra-plate deformation by reactivation of mechanically and rheologically weak pre-existing structures (Brun and Nalpas, 1996;Buiter et al, 2009;Cerca et al, 2004;Gerbault and Willingshofer, 2004;Jammes and Huismans, 2012;Willingshofer et al, 2005).…”

Section: Localization Of Deformation In Continental Intra-plate Settingsmentioning

confidence: 99%

“…Previous modelling studies investigated the reactivation of lithospheric scale weak zones in compression in order to study rifts inversion (Brun and Nalpas, 1996;Buiter et al, 2009;Cerca et al, 2004) or deformation of weak orogenic wedges (Gerbault and Willingshofer, 2004;Jammes and Huismans, 2012;Willingshofer et al, 2005). A more limited number of studies focused on the role of strong domains in the origin of intra-plate mountain belts (Calignano et al, 2015;Keep, 2000).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Asymmetric vs. symmetric deep lithospheric architecture of intra-plate continental orogens

Calignano

Sokoutis

Willingshofer

et al. 2015

Earth and Planetary Science Letters

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Section: Introductionmentioning

confidence: 93%

Section: Localization Of Deformation In Continental Intra-plate Settingsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Asymmetric vs. symmetric deep lithospheric architecture of intra-plate continental orogens

Calignano

Sokoutis

Willingshofer

et al. 2015

Earth and Planetary Science Letters

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“…Changes in the deep Earth structure and/or composition may induce edge-driven convection or focus upwellings in the mantle around the craton [Guillou-Frottier et al, 2012] or may well result in the off-craton and oncraton regions responding differently to unloading and stress [Gilchrist and Summerfield, 1990;Pérez-Gussinyé and Watts, 2005]. Moreover, additional contrasting geophysical characteristics at craton margins such as lateral variations in lithospheric strength, rheology, heat flow, and the presence of pre-existing weak zones have been shown to cause intraplate stresses to build up at the craton margins [Redfield and Osmundsen, 2014;Gueydan et al, 2014;Lenardic et al, 2003;Baptiste et al, 2012;Wang et al, 2014;Calignano et al, 2015;Janney et al, 2010].…”

Section: Mesozoic Evolution: Late Cretaceousmentioning

confidence: 99%

Contrasting Mesozoic evolution across the boundary between on and off craton regions of the South African plateau inferred from apatite fission track and (U‐Th‐Sm)/He thermochronology

et al. 2017

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The timing and mechanisms involved in creating the elevated, low‐relief topography of the South African plateau remain unresolved. Here we constrain the thermal history of the Southwest African plateau since 300 Ma by using apatite fission track (AFT) and (U‐Th‐Sm)/He (AHe) thermochronology. Archean rocks from the center of the Kaapvaal Craton yield AFT ages of 331.0 ± 11.0 and 379.0 ± 23.0 Ma and mean track lengths (MTLs) of 11.9 ± 0.2 and 12.5 ± 0.3 µm. Toward the southwest margin of the craton and in the adjacent Paleozoic mobile belt, AFT ages are significantly younger and range from 58.9 ± 5.9 to 128.7 ± 6.3 Ma and have longer MTLs (>13 µm). The range of sample AHe ages complements the AFT ages, and single‐grain AHe ages for most samples are highly dispersed. Results from joint inverse modeling of these data reveal that the center of the craton has resided at near‐surface temperatures (<60°C) since 300 Ma, whereas the margins of the craton and the off‐craton mobile belt experienced two discrete episodes of cooling during the Cretaceous. An Early Cretaceous cooling episode is ascribed to regional denudation following continental breakup. Late Cretaceous cooling occurs regionally but is locally variable and may be a result of a complex interaction between mantle‐driven uplift and the tectonic setting of the craton margin. Across the entire plateau, samples are predicted to have remained at near‐surface temperatures throughout the Cenozoic, suggesting minimal denudation (<1 km) and relative tectonic stability of the plateau.

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“…Passive margins therefore represent major discontinuities in lithospheric strength. Analog and numerical models in convergent settings, which include two (or possibly more) domains with different material properties, indicate localization of strain along heterogeneities [e.g., England and Houseman, 1985;Dayem et al, 2009;Calignano et al, 2015]. This localization occurs in the weaker material adjacent to the stronger material.…”

Section: 1002/2015jb012202mentioning

confidence: 99%

The role of passive margins on the evolution of Subduction‐Transform Edge Propagators (STEPs)

Nijholt

Govers

2015

JGR Solid Earth

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A Subduction‐Transform Edge Propagator (STEP) is the locus of continual lithospheric tearing which enables subduction of one part of a tectonic plate, while the juxtaposed part remains at the surface. A key question is the propagation direction of active STEPs, and we suspect passive margins to play a critical role in steering STEPs. We investigate the role of passive margins (width, orientation, and lateral strength contrast) on the STEP propagation direction through mechanical finite element models. For straight passive margins, we show that STEPs remain parallel to passive margins when within 15° from a trench‐perpendicular geometry. In other cases, where passive margins change strike ahead of the active STEP, STEPs are captured by passive margins for abrupt strike changes (radius of curvature < lithosphere thickness) less than 25° from trench perpendicular. Outside this window, STEPs will propagate in the original direction. If a strike change (>25°) is made through a large radius of curvature (>lithosphere thickness), STEPs will also propagate along the passive margin. A STEP system evolves toward orthogonality, which may explain why STEP faults are approximately perpendicular to trenches in nature. STEP systems are relatively insensitive to small‐scale details (due to large‐scale stresses), propagating as straight features along rugged passive margins. Surprisingly, magnitudes of lithospheric strength variation across the passive margin and subduction history, which determines location and magnitude of density anomalies in the mantle, are less relevant for the STEP propagation direction.

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Strain localization at the margins of strong lithospheric domains: Insights from analog models

Cited by 38 publications

References 88 publications

Asymmetric vs. symmetric deep lithospheric architecture of intra-plate continental orogens

Asymmetric vs. symmetric deep lithospheric architecture of intra-plate continental orogens

Contrasting Mesozoic evolution across the boundary between on and off craton regions of the South African plateau inferred from apatite fission track and (U‐Th‐Sm)/He thermochronology

The role of passive margins on the evolution of Subduction‐Transform Edge Propagators (STEPs)

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