The South Tibetan detachment system facilitates ultra rapid cooling of granulite‐facies rocks in Sikkim Himalaya

Kellett, Dawn A.; Grujić, Djordje; Coutand, Isabelle; Cottle, John M.; Mukul, Malay

doi:10.1002/tect.20014

Cited by 118 publications

(104 citation statements)

References 120 publications

(276 reference statements)

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“…Nonuniform, spatially variable early to middle Miocene exhumation of rock from midcrustal depths is documented across the GHS, including (1) in southeastern Bhutan (south of Tashigang, Figure ), where ~17–27 km of rapid exhumation in the MCT zone occurred between 18–13 Ma and present at rates of 3 to 9 mm/yr [ Daniel et al ., ], (2) further north in the footwall of the Kakhtang Thrust, rocks were exhumed from midcrustal depths by 21–17 Ma, possibly aided by synchronous slip on the O‐STD and MCT [ Chambers et al ., ; Kellett et al ., , ; Tobgay et al ., ; Warren et al ., ], and (3) in the hanging wall of the Kakhtang Thrust in NW Bhutan (Figure ), where granulitized eclogites experienced 20–44 km of exhumation in 1–2 Myr, implying exhumation rates of 10–44 mm/yr between 15 and 13 Ma, again possibly aided by coeval slip on the I‐STD [ Grujic et al ., ; Kellett et al ., ; Warren et al ., ]. Peak temperature metamorphic ages combined with muscovite 40 Ar/ 39 Ar ages across the GHS and upper LHS suggest very rapid cooling until 13–11 Ma (that may also be partly attributed to isotherm relaxation) and a common GHS‐LHS cooling history by 10 Ma [ Castelli and Lombardo , ; Gansser , ; Kellett et al ., , ; Long et al ., ; Maluski et al ., ; Stüwe and Foster , ]. Combined, these observations closely match predictions from numerical geodynamic models of channel flow tectonics in the Himalaya [ Beaumont et al ., ; Jamieson et al ., , ].…”

Section: Discussionmentioning

confidence: 98%

Geometry and kinematics of the Main Himalayan Thrust and Neogene crustal exhumation in the Bhutanese Himalaya derived from inversion of multithermochronologic data

Coutand

Whipp

Grujić

et al. 2014

J. Geophys. Res. Solid Earth

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Both climatic and tectonic processes affect bedrock erosion and exhumation in convergent orogens, but determining their respective influence is difficult. A requisite first step is to quantify long-term (~10 6 year) erosion rates within an orogen. In the Himalaya, past studies suggest long-term erosion rates varied in space and time along the range front, resulting in numerous tectonic models to explain the observed erosion rate distribution. Here, we invert a large data set of new and existing thermochronological ages to determine both long-term exhumation rates and the kinematics of Neogene tectonic activity in the eastern Himalaya in Bhutan. New data include 31 apatite and five zircon (U-Th)/He ages, and 49 apatite and 16 zircon fission-track ages along two north-south oriented transects across the orogen in western and eastern Bhutan. Data inversion was performed using a modified version of the 3-D thermokinematic model Pecube, with parameter ranges defined by available geochronologic, metamorphic, structural, and geophysical data. Among several important observations, our three main conclusions are as follows: (1) Thermochronologic ages do not spatially correlate with surface traces of major fault zones but appear to reflect the geometry of the underlying Main Himalayan Thrust; (2) our data are compatible with a strong tectonic influence, involving a variably dipping Main Himalayan Thrust geometry and steady state topography; and (3) erosion rates have remained constant in western Bhutan over the last~10 Ma, while a significant decrease occurred at~6 Ma in eastern Bhutan, which we partially attribute to convergence partitioning into uplift of the Shillong Plateau.

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Section: Discussionmentioning

confidence: 98%

Geometry and kinematics of the Main Himalayan Thrust and Neogene crustal exhumation in the Bhutanese Himalaya derived from inversion of multithermochronologic data

Coutand

Whipp

Grujić

et al. 2014

J. Geophys. Res. Solid Earth

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117

257

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“…18 and 15 Ma. Studies along the South Tibetan detachment system in Bhutan and Sikkim documented a similar age progression, in which the growth of 16-15 Ma Y-rich monazite rims was interpreted to record retrograde Greater Himalayan Sequence metamorphism during final stages of Sdirected extrusion (Kellett et al, 2010(Kellett et al, , 2013.…”

Section: Tectonic Significance Of Orogen-parallel Extensionmentioning

confidence: 95%

Mid-Miocene initiation of orogen-parallel extension, NW Nepal Himalaya

et al. 2015

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Geologic field mapping surveys integrated with structural, thermochronological, and geochronological analyses confirm the existence of an orogen-parallel strike-slip-dominated shear zone in the upper Karnali valley of northwestern Nepal. This shear zone obliquely cuts through the upper Greater Himalayan Sequence and is characterized by a S-dipping, high-strain foliation and intensely developed ESE-WNW-trending, shallow-plunging mineral elongation lineation. Monazite grains within the Greater Himalayan Sequence are deformed and transposed parallel to the orogen-parallel shear zone and ESE-WNW elongation lineations. In situ U-Th/Pb monazite geochronology constrains metamorphism between 19 and 15 Ma, which is consistent with the timing of Neohimalayan metamorphism and S-directed extrusion of the Greater Himalayan Sequence across the Himalaya, and it is therefore interpreted to have preceded orogen-parallel strike-slip deformation. Mineral deformation mechanisms and quartz c-axis patterns of orogen-parallel fabrics record a rapid increase in temperature of deformation from ~350 °C along upper levels of the shear zone to greater than 630 °C at ~2.5 km depth structurally below the shear zone. Symmetric quartz c-axis fabrics further suggest deformation included a significant component of pure shear. The 40 Ar/ 39 Ar thermochronology of foliation-defining muscovite indicates that orogen-parallel shearing was active in the area between ca. 13 and 10 Ma while temperatures cooled through the muscovite closure temperature for argon. By integrating these data with the current understanding of tectonic processes in the Himalaya, we interpret a transition from S-directed extrusion of the Greater Himalayan Sequence to orogen-parallel extension between ca. 15 and 13 Ma in the upper Karnali valley. Integration of our findings with chronological constraints from other migmatite-cored domes supports the growing recognition of a Himalayan-wide mid-Miocene initiation of orogen-parallel extension. GEOLOGIC SETTINGThe geology of the Himalaya consists of four distinct lithotectonic domains bounded by crustal-scale fault systems, all of which are laterally continuous across the length of the orogen (Fig. 1A). The two northernmost LITHOSPHERE GSA Data Repository Item 2015204

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“…As geochronological approaches could not prove with certainty whether or not an out-of-sequence thrust exists inside the GHC, input from structural geology and metamorphic petrology might help to establish or refute the out-of-sequence thrust (Kellett et al 2013). For example, presuming a Himalayan D 2 deformation of top-to-the-south/SW ductile shear at c. 25 Ma Fig.…”

Section: Greater Himalayan Crystallinesmentioning

confidence: 99%

“…If this is proved, it could be an important input to understanding the seismicity within the GHC (Herman et al 2010). Kellett et al (2013) pointed out that if one of the strands of the South Tibetan Detachment acted as a passive roof structure, out-of-sequence thrusting is not required in the tectonics of the GHC. However, this argument does not negate the presence of an out-of-sequence thrust.…”

Section: Greater Himalayan Crystallinesmentioning

confidence: 99%

A review on out-of-sequence deformation in the Himalaya

Mukherjee

2015

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The South Tibetan detachment system facilitates ultra rapid cooling of granulite‐facies rocks in Sikkim Himalaya

Cited by 118 publications

References 120 publications

Geometry and kinematics of the Main Himalayan Thrust and Neogene crustal exhumation in the Bhutanese Himalaya derived from inversion of multithermochronologic data

Geometry and kinematics of the Main Himalayan Thrust and Neogene crustal exhumation in the Bhutanese Himalaya derived from inversion of multithermochronologic data

Mid-Miocene initiation of orogen-parallel extension, NW Nepal Himalaya

A review on out-of-sequence deformation in the Himalaya

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