Active tectonics in Eastern Lunana (NW Bhutan): Implications for the seismic and glacial hazard potential of the Bhutan Himalaya

Meyer, Michael C.; Wiesmayr, Gerhard; Brauner, Marygail K.; Häusler, Hermann; Wangda, D.

doi:10.1029/2005tc001858

Cited by 35 publications

(27 citation statements)

References 59 publications

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“…Spatially, seismic gaps along the Himalayan arc can be as long as 800 km (Avouac, 2007). It has been argued that strike-slip faulting is more active in the High Himalaya than previously recognized (Murphy and Copeland, 2005;Li and Yin, 2008;Meyer et al, 2006;Velasco et al, 2007).…”

Section: Active Structures In the Himalayamentioning

confidence: 98%

Active structures of the Himalayan-Tibetan orogen and their relationships to earthquake distribution, contemporary strain field, and Cenozoic volcanism

Taylor¹,

Yin²

2009

Geosphere

416

277

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We have compiled the distribution of active faults and folds in the HimalayanTibetan orogen and its immediate surrounding regions into a web-based digital map. The main product of this study is a compilation of active structures that came from those documented in the literature and from our own interpretations based on satellite images and digital topographic data. Our digital tectonic map allows a comparison between the distribution and kinematics of active faults with the distribution and focal mechanisms of earthquakes. The active tectonic map is also compared with the contemporary velocity fi eld, obtained by global positioning system studies, that allows a better assessment of partitioning of decadal strain-rate fi elds across individual active structures that may have taken tens of thousands of years to a million years to develop. The active tectonic map provides a basis to evaluate whether the syncollisional late Cenozoic volcanism in Tibet was spatially related to the distribution and development of the active faults in the same area. These comparisons lead to the following fi ndings: (1) Tibetan earthquakes >M5 correlate well with mappable surface faults; (2) the short-term strain-rate fi eld correlates well with the known kinematics of the active faults and their geologic slip rates; and (3) Tibetan Neogene-Quaternary volcanism is controlled by major strike-slip faults along the plateau margins but has no clear relationship with active faults in the plateau interior. Although not explored in this study, our digital tectonic map and the distribution of Cenozoic volcanism in Tibet can also be used to correlate surface geology with geophysical properties such as seismic velocity variations and shear wave-splitting data across the Himalaya and Tibet.

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Section: Active Structures In the Himalayamentioning

confidence: 98%

Active structures of the Himalayan-Tibetan orogen and their relationships to earthquake distribution, contemporary strain field, and Cenozoic volcanism

Taylor¹,

Yin²

2009

Geosphere

416

277

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“…1). In Bhutan, the work of Jangpangi (1974) and Gansser (1983) laid a foundation for the general geology that led to prolifi c studies across the country in the past three decades (Ray et al, 1989;Swapp and Hollister, 1991;Ray, 1995;Bhargava, 1995;Edwards et al, 1996;Grujic et al, 1996Grujic et al, , 2002Grujic et al, , 2006Davidson et al, 1997;Stüwe and Foster, 2001;Wiesmayr et al, 2002;Daniel et al, 2003;Tangri et al, 2003;Baillie and Norbu, 2004;Carosi et al, 2006;Meyer et al, 2006;Richards et al, 2006;Drukpa et al, 2006;Hollister and Grujic, 2006;McQuarrie et al, 2008). Following the traditional defi nition of major Himalayan structures and lithologic units by Heim and Gansser (1939), the Bhutan Himalaya is divided into the Lesser Himalayan Sequence, Greater Himalayan Crystalline Complex, and Tethyan Himalayan Sequence units bounded by the Main Boundary thrust below, the Main Central thrust in the middle, and the later discovered South Tibet detachment at the top ( Fig.…”

Section: Bhutan Himalayamentioning

confidence: 99%

Geologic correlation of the Himalayan orogen and Indian craton: Part 2. Structural geology, geochronology, and tectonic evolution of the Eastern Himalaya

Yin¹,

Dubey²,

Kelty³

et al. 2009

Geological Society of America Bulletin

279

276

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Despite being the largest active collisional orogen on Earth, the growth mechanism of the Himalaya remains uncertain. Current debate has focused on the role of dynamic inter action between tectonics and climate and mass exchanges between the Himalayan and Tibetan crust during Cenozoic India-Asia collision. A major uncertainty in the debate comes from the lack of geologic information on the eastern segment of the Himalayas from 91°E to 97°E, which makes up about one-quarter of the mountain belt. To address this issue, we conducted detailed fi eld mapping, U-Pb zircon age dating, and 40 Ar/ 39 Ar thermo chronology along two geologic traverses at longitudes of 92°E and 94°E across the eastern Himalaya. Our dating indicates the region experienced magmatic events at 1745-1760 Ma, 825-878 Ma, 480-520 Ma, and 28-20 Ma. The fi rst three events also occurred in the northeastern Indian craton, while the last is unique to the Hima laya. Correlation of magmatic events and age-equivalent lithologic units suggests that the eastern segment of the Himalaya was constructed in situ by basement-involved thrusting, which is inconsistent with the hypothesis of high-grade Himalaya rocks derived from Tibet via channel fl ow. The Main Central thrust in the eastern Himalaya forms the roof of a major thrust duplex; its northern part was initiated at ca. 13 Ma, while the southern part was initiated at ca. 10 Ma, as indicated by 40 Ar/ 39 Ar thermochronometry. Crustal thickening of the Main Central thrust hanging wall was expressed by discrete ductile thrusting between 12 Ma and 7 Ma, overlapping in time with motion on the Main Central thrust below. Restoration of two possible geologic cross sections from one of our geologic traverses, where one assumes the existence of pre-Cenozoic deformation below the Himalaya and the other assumes fl at-lying strata prior to the IndiaAsia collision, leads to estimated shortening of 775 km (~76% strain) and 515 km (~70% strain), respectively. We favor the presence of signifi cant basement topog raphy below the eastern Himalaya based on projections of early Paleo zoic structures from the Shillong Plateau (i.e., the Central Shillong thrust) located ~50 km south of our study area. Since northeastern India and possibly the eastern Himalaya both experienced early Paleozoic contraction, the estimated shortening from this study may have resulted from a combined effect of early Paleozoic and Cenozoic deformation.

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“…Preserved at the base of klippen, the Outer South Tibetan Detachment shear zone (O‐STD) [ Kellett et al ., ] is characterized by top‐down‐to‐the‐north shearing with a strong component of vertical shortening and was active between circa 24–22 Ma and circa 16 Ma [ Chambers et al ., ; Corrie et al ., ; Grujic et al ., ; Kellett et al ., , ; Tobgay et al ., ]. Straddling the Bhutan‐Tibet border, the Inner South Tibetan Detachment (I‐STD) was active until circa 11 Ma as a ductile shear zone [ Edwards et al ., , ; Kellett et al ., ; Wu et al ., ] and is crosscut by steep brittle normal and strike‐slip faults of minor magnitude, which offset Quaternary moraines [ Meyer et al ., ; Wiesmayr et al ., ].…”

Section: Geologic Settingmentioning

confidence: 99%

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

115

257

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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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Active tectonics in Eastern Lunana (NW Bhutan): Implications for the seismic and glacial hazard potential of the Bhutan Himalaya

Cited by 35 publications

References 59 publications

Active structures of the Himalayan-Tibetan orogen and their relationships to earthquake distribution, contemporary strain field, and Cenozoic volcanism

Active structures of the Himalayan-Tibetan orogen and their relationships to earthquake distribution, contemporary strain field, and Cenozoic volcanism

Geologic correlation of the Himalayan orogen and Indian craton: Part 2. Structural geology, geochronology, and tectonic evolution of the Eastern Himalaya

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

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