Quantifying the impact of mechanical layering and underthrusting on the dynamics of the modern India‐Asia collisional system with 3‐D numerical models

Lechmann, S. M.; Schmalholz, Stefan M.; Hetényi, György; May, David A.; Kaus, Boris

doi:10.1002/2012jb009748

Cited by 22 publications

(36 citation statements)

References 113 publications

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“…Over 40 million random Lagrangian markers are deployed evenly in the Eulerian cells. Table 1 ( Jiménez-Munt et al, 2008;Lechmann et al, 2014;Priestley et al, 2008;Xu et al, 2015;Yuan et al, 1997;Zhao et al, 1993). One extra sticky air layer (20 km thick) is imposed in the top of the model domain, approximating the crustal surface as an internal free surface (Schmeling, 2008).…”

Section: Model Setupmentioning

confidence: 99%

The Mechanism and Dynamics of N‐S Rifting in Southern Tibet: Insight From 3‐D Thermomechanical Modeling

et al. 2018

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N‐S trending rifts are widely distributed in southern Tibet, suggesting that this region is under E‐W extension, behind the N‐S collision between the Eurasia and India plates. Geophysical anomalies and Miocene magma extrusions indicate the presence of dispersed weak zones in the middle to lower crust in southern Tibet. These weak zones are partially located underneath the N‐S rifting systems. In order to study the formation of rifts in collision zones, we have developed a high‐resolution 3‐D thermomechanical model of continental lithosphere with bidirectional compressional‐extensional deformation, and spatially localized weak and low‐density zones in the middle to lower crust. Our numerical experiments systematically reproduce the development of N‐S trending rifts. Model results reveal that the weak middle to lower crust triggers the development of normal faults in the upper crust and surface uplift, whereas regions without such weak layer or with small‐scale weak zones are characterized by strike‐slip faulting. Geodynamic properties (density, depth, and geometry) of the weak middle to lower crust and Moho temperature notably influence the rifting pattern. In addition, rifting formation is critically controlled by large E‐W extension, with the ratio of extensional to compressional strain rate larger than 1.5 in the model with continuous weak middle crust. Our simulated rifting patterns correlate well with the observations in southern Tibet; we conclude that a combination of the bidirectional compression‐extension and the presence of locally weak middle to lower crust triggered the development of the rifting systems in southern Tibet.

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Section: Model Setupmentioning

confidence: 99%

The Mechanism and Dynamics of N‐S Rifting in Southern Tibet: Insight From 3‐D Thermomechanical Modeling

et al. 2018

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“…Previous authors have used 3‐D thermos‐mechanical simulations that derive viscosity structure from laboratory flow laws and/or assumed temperature profiles to investigate the role of the subducted Indian plate, lateral crustal strength variations within Asia, and preexisting strong lithospheric blocks in the development of topography within the IN‐EU collision zone (Capitanio & Replumaz, ; Chen et al, ; Chen & Gerya, ; Cook & Royden, ; Lechmann et al, , ; Püsök & Kaus, ; Yang & Liu, , ). These results highlighted the need for variable variations in both vertical and lateral strength in order to reproduce observed topography.…”

Section: Introductionmentioning

confidence: 99%

Impact of Lithospheric Strength Distribution on India‐Eurasia Deformation From 3‐D Geodynamic Models

Bischoff

Flesch

2019

JGR Solid Earth

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Models for continental lithospheric strength are not well resolved due to a lack of direct measurement; however, numerical simulations provide means for evaluating the physicality of endmember cases. We simulate the 3-D dynamics of continental lithosphere within the India-Eurasia collision zone and compare results to observed deformation. Three-dimensional lithospheric deformation is approximated with creeping flow in a layered spherical cap. We partition strength with depth according to endmember models, using laterally varying estimates of vertically averaged effective viscosity to constrain the absolute values of 3-D viscosity in the upper crustal and mantle layers. Comparisons between dynamic solutions and observed geophysical data indicate: (1) Deformation within the subducted Indian slab is required to simulate uplift along the entire Himalayan front with 10 22 Pa·s representing an upper bound for slab strength.(2) Along-strike variations in crustal strength are necessary to match surface observations. (3) Balance of gravitational forces acting on Tibetan lithosphere with a weak lower crust are able to replicate observed vertical deformation patterns. A west-to-east decrease in the lateral extent of the underthrust Indian slab is required for reproducing observed surface motions in Tibet. Geodynamic simulations yield subsidence in southern Qiangtang and Southeast Asia consistent with global positioning system-derived dilatation. We note a trade-off between upper crustal strength and surface velocity rotation around the Eastern Himalayan syntaxis. Simulations with stronger upper crust replicate velocities in western Tibet but not the east, while those with weaker upper crust produce observed rotation in eastern Tibet but overpredict magnitudes to the west.

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“…The primary result of the modeling exercise is to demonstrate that a simple vertically homogeneous TVS with kinematic boundary conditions determined from relative plate velocities, body forces set by the distribution of GPE, an approximate representation of crustal faults using lateral variations in effective viscosity, and realistic coupling of the Pamir and Tibet fits the full GPS surface velocity field within uncertainties for the entire Indo-Asian collision from Afghanistan to SE Asia. Quantitative comparisons of the best TVS solution to fully 3D forward models that incorporate additional structural and dynamic complexity based on a priori additional knowledge of the region, such as stresses applied by a coherent lithospheric slab in the Pamir, the development of very weak lower crust in Tibet (Royden et al, 2008), sublithospheric tractions (Ghosh et al, 2006), or the introduction of 3D architecture (Lechmann et al, 2014;Yang & Liu, 2013), demonstrate that increased complexity does little better than our minimally complex formulation in reproducing the observed surface velocities, and therefore violates an information criterion of model efficiency. On the other hand, simpler models than the TVS, such as a three-block elastic formulation (Avouac & Tapponnier, 1993) or a homogeneous Newtonian sheet (England & McKenzie, 1982), perform so poorly at matching the high spatial resolution of available surface velocities and topography that they also violate the information criterion.…”

Section: Discussionmentioning

confidence: 99%

“…Geophysical Research Letters 10.1002/2017GL076503 conditions in westernmost Tibet that preclude westward advection of mass (i.e., strike-slip only) (e.g., Flesch et al, 2001;Lechmann et al, 2014;Vergnolle et al, 2007;Yang & Liu, 2013) with continuity across the northern Karakorum Fault (e.g., Robinson, 2009), shortening in the Pamir (Ischuk et al, 2013), and westward extension into the Tajik Depression (Ischuk et al, 2013). This version of the forward model also includes a more highly spatially resolved effective viscosity and GPE distribution.…”

Section: >250mentioning

confidence: 99%

Limitations on Inferring 3D Architecture and Dynamics From Surface Velocities in the India‐Eurasia Collision Zone

Flesch

Bendick

Bischoff

2018

Geophysical Research Letters

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Surface velocities derived from Global Positioning System observations and Quaternary fault slip rates measured throughout an extended region of high topography in South Asia vary smoothly over thousands of kilometers and are broadly symmetrical, with components of both north‐south shortening and east‐west extension relative to stable Eurasia. The observed velocity field does not contain discontinuities or steep gradients attributable to along‐strike differences in collision architecture, despite the well‐documented presence of a lithospheric slab beneath the Pamir but not the Tibetan Plateau. We use a modified Akaike information criterion (AICc) to show that surface velocities do not efficiently constrain 3D rheology, geometry, or force balance. Therefore, although other geophysical and geological observations may indicate the presence of mechanical or dynamic heterogeneities within the Indian‐Asian collision, the surface Global Positioning System velocities contain little or no usable information about them.

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Quantifying the impact of mechanical layering and underthrusting on the dynamics of the modern India‐Asia collisional system with 3‐D numerical models

Cited by 22 publications

References 113 publications

The Mechanism and Dynamics of N‐S Rifting in Southern Tibet: Insight From 3‐D Thermomechanical Modeling

The Mechanism and Dynamics of N‐S Rifting in Southern Tibet: Insight From 3‐D Thermomechanical Modeling

Impact of Lithospheric Strength Distribution on India‐Eurasia Deformation From 3‐D Geodynamic Models

Limitations on Inferring 3D Architecture and Dynamics From Surface Velocities in the India‐Eurasia Collision Zone

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