Post‐Miocene Erosion in Central Nepal Controlled by Midcrustal Ramp Position, Duplex Growth, and Dynamically Maintained Elastic Strain

Johnston, Shelby; Cannon, J. M.; Copeland, Peter

doi:10.1029/2020tc006291

Cited by 7 publications

(13 citation statements)

References 99 publications

(281 reference statements)

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“…PT2 exhibits along‐strike variations and is usually collocated with features that define the active‐uplift front of the Himalaya (e.g., Duncan et al., 2003; Harvey et al., 2015; Morell et al., 2015). The young cooling ages along this zone suggest rapid exhumation (e.g., Blythe et al., 2007; Copeland et al., 1991; Johnston et al., 2020; Wobus et al., 2003). The above‐mentioned bifurcation of the high‐slope zone in western Nepal Himalaya obscures the plateau‐taper pattern of the topography there (Figure 1).…”

Section: Geological Settingmentioning

confidence: 99%

Megathrust Heterogeneity, Crustal Accretion, and a Topographic Embayment in the Western Nepal Himalaya: Insights From the Inversion of Thermochronological Data

et al. 2022

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Between 81°30ʹE and 83°E, the Himalayan range's “perfect” arcuate shape is interrupted by an embayment. We hypothesize that thrust geometry and duplexing along the megathrust at midlower‐crustal depths play a leading role in growth of the embayment as well the southern margin of the Tibetan plateau. To test this hypothesis, we conducted thermokinematic modeling of published thermochronologic data from the topographic and structural embayment in the western Nepal Himalaya to investigate the three‐dimensional geometry and kinematics of the megathrust at midlower‐crustal depths. Models that can best reproduce observed cooling ages suggest that the megathrust in the western Nepal Himalaya is best described as two ramps connected by a long flat that extends further north than in segments to the east and west. These models suggest that the high‐slope zone along the embayment lies above the foreland limb of an antiformal crustal accretion zone on the megathrust with lateral and oblique ramps at midlower‐crustal depths. The lateral and oblique ramps may have initiated by ca. 10 Ma. This process may have controlled along‐strike variation in Himalayan‐plateau growth and therefore development of the topographic embayment. Finally, we analyze geological and morphologic features and propose an evolution model in which landscape and drainage systems across the central‐western Himalaya evolve in response to crustal accretion at depth and the three‐dimensional geometry of the megathrust. Our work highlights the importance of crustal accretion at different depths in orogenic‐wedge growth and that the midlower crustal accretion determines the location of plateau edge.

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Section: Geological Settingmentioning

confidence: 99%

Megathrust Heterogeneity, Crustal Accretion, and a Topographic Embayment in the Western Nepal Himalaya: Insights From the Inversion of Thermochronological Data

et al. 2022

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“…Second, peak erosion and locally higher erosion patterns, indicated by the detrital muscovite dating, are spatially coincident with the interpreted midcrustal ramp and the ramp's north, which is suggested to reflect an uplift pattern caused by duplexing (e.g., Johnston et al, 2020). Third, repetitions of stratigraphic units, evidence of thrust sheets repeatedly breaking forward and stepping up from the common stratigraphic level, are found in geological cross-sections nearly the entire Himalayan arc (e.g., Mitra and Boyer, 2020;Long and Robinson, 2021)-from Pakistan (Jadoon and Frisch, 1997), the Kashmir Himalaya (Gavillot et al, 2018), the northwest Indian Himalaya (Yu et al, 2015), west, central andeast Nepal Himalaya (e.g., DeCelles et al, 2001;Robinson et al, 2006;Bhattacharyya and Mitra, 2009;Khanal et al, 2015;Ghoshal et al, 2020), to the Bhutan Himalaya (e.g., Long et al, 2011;McQuarrie et al, 2019).…”

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confidence: 83%

“…Fourth, the continuously southward migration of the midcrustal ramps, related to the translation of the duplex, has also been detected via various indices of uplifting across a wide range of timescales (e.g., Grandin et al, 2012;Johnston et al, 2020).…”

mentioning

confidence: 99%

Supplemental Material: Duplex kinematics reduces both frontal advance and seismic moment deficit in the Himalaya

Hu¹,

Stevens²

2022

Preprint

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“…Cooling ages from low-T thermochronology can provide information on erosion and hence on tectonic and geomorphic processes (Braun et al, 2006). Thermochronological ages from central Nepal are generally Pliocene and younger, attesting to rapid, high-magnitude erosion (Blythe et al, 2007;Herman et al, 2010;Johnston et al, 2020;Nadin & Martin, 2012;Robert et al, 2011 (Blythe et al, 2007;DeCelles et al, 2020;Herman et al, 2010;Nadin & Martin, 2012;Robert et al, 2009Robert et al, , 2011Sakai et al, 2013;Streule et al, 2012;van der Beek et al, 2016). At regional scale, cooling ages in central Nepal are younger than cooling ages in western Nepal (Figures 6c and 6d).…”

Section: Thermochronology As Proxy For Erosionmentioning

confidence: 99%

“…The northern edge of the erosional bight coincides DECELLES AND CARRAPA 10.1029/2020JB021256 5 of 30 Wobus et al (2003), the approximate line north of which the geodetically derived interseismic coupling along the basal décollement drops to near zero (Ader et al, 2012), the Dang, Deukhury, and Chitwan wedge-top basins, and major rivers of the Karnali and Kosi River watersheds. with a nearly straight, ∼235 km long band of steep fluvial channel segments (e.g., Cannon et al, 2018;Johnston et al, 2020;Wobus et al, 2003) and abrupt hillslope steepening referred to as physiographic transition "PT 2 " by Hodges et al (2001) and Wobus et al (2003). The Narayani basin protrudes into topographic Tibet at its northwestern and northeastern corners by virtue of the high elevation Thakkhola and Gyirong grabens, respectively, which are Miocene-Holocene extensional basins bounded by steep normal faults that strike roughly north-south and dip inward toward the Narayani basin (Colchen, 1999;DeCelles et al, 2018;Hurtado et al, 2001;Shen et al, 2016;Xu et al, 2012).…”

Section: Geomorphologymentioning

confidence: 99%

Coupled Rapid Erosion and Foreland Sedimentation Control Orogenic Wedge Kinematics in the Himalayan Thrust Belt of Central Nepal

DeCelles

Carrapa

2021

JGR Solid Earth

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Spatial and temporal coincidence among rapid Pliocene-Holocene bedrock exhumation, development of a topographic bight, abundant monsoonal precipitation, accumulation of anomalously thick proximal foreland basin deposits, and development of an opposite-polarity salient-reentrant couple on the two most frontal major thrust faults in the Himalayan orogenic wedge of central Nepal provide a basis for a model that links these diverse phenomena and could be operating in other parts of the frontal Himalaya. Rapid bedrock erosion is documented by a concentration of young (<5 Ma) lowtemperature thermochronologic ages in the Narayani River catchment basin. Where the river exits the Lesser Himalayan Zone, the Main Boundary thrust has a 15-km-amplitude reentrant. Directly south of the reentrant lies the ∼50 km wide Chitwan wedge-top basin, which is confined by a large salient on the Main Frontal thrust. Rapid erosion and sediment flux out of the Narayani catchment basin, possibly due to anomalously intense monsoonal precipitation in this topographically depressed region of central Nepal, causes greater flexural subsidence and surface aggradation in the foreland, both of which increase initial wedge taper and render this region more susceptible to anomalous forward propagation of the thrust front. Analysis of the modern and post-early Miocene taper history of the thrust belt suggests that rapid erosion hindered forward propagation of the contemporaneous Main Boundary thrust, but simultaneously produced conditions in the foreland that eventually elevated initial taper to a critical/supercritical value promoting forelandward propagation of the Main Frontal thrust. This analysis has implications for large damaging earthquakes in the Himalaya.

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Post‐Miocene Erosion in Central Nepal Controlled by Midcrustal Ramp Position, Duplex Growth, and Dynamically Maintained Elastic Strain

Cited by 7 publications

References 99 publications

Megathrust Heterogeneity, Crustal Accretion, and a Topographic Embayment in the Western Nepal Himalaya: Insights From the Inversion of Thermochronological Data

Megathrust Heterogeneity, Crustal Accretion, and a Topographic Embayment in the Western Nepal Himalaya: Insights From the Inversion of Thermochronological Data

Supplemental Material: Duplex kinematics reduces both frontal advance and seismic moment deficit in the Himalaya

Coupled Rapid Erosion and Foreland Sedimentation Control Orogenic Wedge Kinematics in the Himalayan Thrust Belt of Central Nepal

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