Response of Surface Erosion to Crustal Shortening and its Influence on Tectonic Evolution in Fold‐and‐Thrust Belts: Implications From Sandbox Modeling on Tectonic Geomorphology

Mao, Yuqiong; Li, Yiquan; Yan, Bing; Jia, Dong; Chen, Yingying

doi:10.1029/2020tc006515

Cited by 11 publications

(17 citation statements)

References 91 publications

(158 reference statements)

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“…The redistribution of mass in CR 0.19 0 results in an increase in the thrust spacing and consequently in the width of the wedge (e.g., Fillon et al, 2013;Storti & McClay, 1995). Mao et al (2021) found a good correlation between lower shortening rates and longer intervals between structures, assessing that the thickness of sediments opposes the displacement of the thrusts.…”

Section: Mass Redistribution Controls Wedge Morphologymentioning

confidence: 95%

Sediment Recycling and the Evolution of Analog Orogenic Wedges

et al. 2022

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The evolution of mountain belts results from the interaction between processes operating at different scales and depths. Tectonic processes build relief by progressively stacking slices of buoyant crustal material and increasing mean elevation by isostasy. Rivers and glaciers erode the landscape and transport sediments lowering the mean elevation. The competition between tectonic and surface processes should lead orogen to an equilibrium, a steady state configuration (e.g., Willett & Brandon, 2002) that is sensitive to changes in climate, lithology, and/ or uplift rate (e.g.

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Section: Mass Redistribution Controls Wedge Morphologymentioning

confidence: 95%

Sediment Recycling and the Evolution of Analog Orogenic Wedges

et al. 2022

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“…In active fold-thrust belts around the world, such as the Aconcagua fold-thrust belt in Argentina (Hilley et al, 2004), the central Andes fold-thrust belt in Bolivia (Horton, 1999;McQuarrie et al, 2008), the central Apennines fold-thrust belt in Italy (Scisciani and Montefalcone, 2006;Wu and McClay, 2011), and the Taiwan fold-thrust belt in China (Dahlen and Suppe 1988;Dadson et al, 2003;Wu and McClay, 2011), the roles of different synkinematic erosion and/or sedimentary loading, probably caused by long-term along-strike climatic variations (McQuarrie et al, 2008), on the generation and evolution of thrust faults in these fold-thrust belts (thrust wedges) have been interpreted and discussed by the Coulomb wedge model theory (e.g., Davis et al, 1983;Dahlen et al, 1984;Dahlen and Suppe 1988) and experimental simulations (e.g., Storti and Mcclay, 1995;Persson and Sokoutis, 2002;Simpson, 2006;Graveleau and Dominguez, 2008;Cruz et al, 2010;Cruz et al, 2011;Wu and McClay, 2011;Malavieille, 2011;Steer et al, 2014;Sun et al, 2016;Sun et al, 2021;Luo et al, 2021;Mao et al, 2021). Theoretical analysis and modeling results have all shown that syntectonic erosion reduced the number of major forwardvergent thrusts, and increased exhumation and thrust activities at the rear of the thrust wedge, resulted in out-of-sequence thrusting and fault reactivation in the wedge hinterland, and inhibited the forward propagation of the deformation front into the foreland.…”

Section: Influence Of Erosion and Sedimentary Loading On Activity Of Thrust Faults In Lmsmentioning

confidence: 99%

“…Moreover, in the LMS foldthrust belt, Li et al (2016), Li C. et al (2018) identified growth strata and revealed early to late Pleistocene activity on the Range Front blind thrust. Recently, by using sandbox analog experiments, Luo et al (2021) investigated the influences of differential rates of synkinematic erosion and sedimentation on wedge geometries and fault activities during the development of thrust wedges, and further discussed the influences from the change of erosion-sedimentation along the strike on the structural evolution of the LMS fold-thrust belt; Mao et al (2021) have shown that surface erosion and sedimentation affected the position, morphology, lateral propagation, and connection of new structures in fold-thrust belts. Overall, sufficient studies have shown the important relationship between surface processes (denudation and/or deposition) and tectonic processes (fault activity) in fold-thrust belts, although there are still some different viewpoints on the main controlling factors.…”

Section: Introductionmentioning

confidence: 99%

Influence of Regional Erosion and Sedimentary Loading on Fault Activities in Active Fold-Thrust Belts: Insights From Discrete Element Simulation and the Southern and Central Longmen Shan Fold-Thrust Belt

Yin

et al. 2021

Front. Earth Sci.

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Four groups of discrete element models (DEMs) were set-up to simulate and analyze the influence of regional erosion and sedimentary loading on the formation and spatial-temporal evolution of faults in the southern and central Longmen Shan (LMS) active fold-thrust belt. The interior characteristics of faults in the southern and central LMS fold-thrust belt were also evaluated during the interaction of tectonic processes and surface processes according to the stress-strain analysis from DEM results. The results showed that synkinematic erosion promoted the reactivation of pre-existing faults in thrust wedges and also retarded the formation and development of new incipient faults in the pre-wedge regions. Meanwhile, synkinematic sedimentation also delayed the development of new incipient faults in the pre-wedge regions by promoting the development of thrust faults in the front of thrust wedges, causing these thrust wedges in supercritical stages with relatively narrow wedge lengths. According to these DEM results, we infer that: 1) The characteristics of erosion and sedimentation in the central and southern LMS have important influences on the activities of large faults which are extended into the deep detachment layer; 2) Besides differential erosion, the differential sedimentary loading may also be one of the important factors for the along-strike differential evolution of the LMS fold-thrust belt. This kind of differential deposition may lead to differential fault activity and uplift in the interior thrust wedge and pre-wedge region in the central and southern LMS; 3) Compared to the northern LMS, the central LMS and southern LMS is more conducive to the occurrence of earthquakes, because of synkinematic sedimentation (such as the growth of Chengdu plain) has a greater blocking effect on the stress propagation and strain convergence on the fault planes of front faults of an active thrust wedge.

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“…Since the pioneer paper of Hubbert (1937) [25], many studies have focused on analog models scaling (e.g., [19,20,[26][27][28]). Here, the scaling of our experiments was done by taking into account dynamic, geometric, and kinematic similarity criteria between model parameters and field observations.…”

Section: Scalingmentioning

confidence: 99%

“…A few previous studies combined analog and numerical approaches for studying the surface and tectonic processes at the crustal scale (e.g., [18]). This method is currently used to estimate erosion and sedimentation processes according to the granular composition [19] and the erosion influence on tectonics in a context of crustal shortening [20]. Following this approach, we investigated the evolution of a geomorphologic marker by comparing analog and numerical models.…”

Section: Introductionmentioning

confidence: 99%

Morphotectonic Evolution of an Alluvial Fan: Results of a Joint Analog and Numerical Modeling Approach

et al. 2021

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Surface topography results from complex couplings and feedbacks between tectonics and surface processes. We combine analog and numerical modeling, sharing similar geometry and boundary conditions, to assess the topographic evolution of an alluvial fan crossed by an active thrust fault. This joint approach allows the calibration of critical parameters constraining the river deposition–incision laws, such as the settling velocity of suspended sediments, the bed-rock erodibility, or the slope exponent. Comparing analog and numerical models reveals a slope-dependent threshold process, where a critical slope of ca. 0.081 controls the temporal evolution of the drainage network. We only evidence minor topographic differences between stable and stick-slip fault behavior localized along the fault scarp. Although this topographic signature may increase with the slip rate and the return period of slip events, it remains slight compared to the cumulated displacement along the fault scarp. Our results demonstrate that the study of morphology cannot be used alone to study the slip mode of active faults but can be a valuable tool complementing stratigraphic and geodetic observations. In contrast, we underline the significant signature of the distance between the fault and the sediment source, which controls the degree of channels incision and the density of the drainage network.

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Response of Surface Erosion to Crustal Shortening and its Influence on Tectonic Evolution in Fold‐and‐Thrust Belts: Implications From Sandbox Modeling on Tectonic Geomorphology

Abstract: The interaction between structural deformation and geomorphic processes is an active research topic in earth system sciences (

Cited by 11 publications

References 91 publications

Sediment Recycling and the Evolution of Analog Orogenic Wedges

Sediment Recycling and the Evolution of Analog Orogenic Wedges

Influence of Regional Erosion and Sedimentary Loading on Fault Activities in Active Fold-Thrust Belts: Insights From Discrete Element Simulation and the Southern and Central Longmen Shan Fold-Thrust Belt

Morphotectonic Evolution of an Alluvial Fan: Results of a Joint Analog and Numerical Modeling Approach

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