Evolution of the Kangmar Dome, southern Tibet: Structural, petrologic, and thermochronologic constraints

Lee, Jeffrey; Hacker, Bradley R.; Dinklage, W.S.; Yü, Wang; Gans, Phillip B.; Calvert, Andrew T.; Wan, Jie; Chen, Wenji; Blythe, Ann E.; McClelland, William C.

doi:10.1029/1999tc001147

Cited by 269 publications

(282 citation statements)

References 58 publications

(6 reference statements)

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“…In addition, D2 foliation is, on the whole, most strongly developed in the region adjacent to the granite bodies and becomes less strongly developed with increasing distance from the granite bodies. These features are strikingly similar to those of D2 recognized for the Kangmar dome (Chen et al 1990, Lee et al 2000.…”

Section: Deformation Phases and Their Distributionsupporting

confidence: 66%

“…However, this deformation has not been well-documented. Even for the Kangmar dome (Figure 1), the most accessible and well-documented metamorphic dome, two contrasting views exist about the kinematic nature of the associated deformation: (i) dominantly top-to-the north shear (Chen et al 1990); and (ii) bulk pure shear reflected by a combination of top-to the north and top-to the south senses of shear in the northern and the southern parts of the dome, respectively (Lee et al 2000). A second important point to be assessed is the origin of the granitic cores to the metamorphic domes.…”

mentioning

confidence: 99%

“…A second important point to be assessed is the origin of the granitic cores to the metamorphic domes. In the Kangmar dome the granite is thought to represent part of the basement root complex and not an intrusion during the Himalayan orogeny (Chen et al 1990, Lee et al 2000. To obtain new insights into these issues and to compare our new results with the Kangmar examples, structural and geochemical studies were carried in a metamorphosed region of Malashan area, located about 400 km west of the Kangmar dome (Figure 1).…”

mentioning

confidence: 99%

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The Malashan metamorphic complex in southern Tibet: Dominantly top-to-the north deformation and intrusive origin of its associated granites

Aoya

Wallis

Kawakami

et al. 2008

Himalayan Journal of Sciences

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Section: Deformation Phases and Their Distributionsupporting

confidence: 66%

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confidence: 99%

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confidence: 99%

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The Malashan metamorphic complex in southern Tibet: Dominantly top-to-the north deformation and intrusive origin of its associated granites

Aoya

Wallis

Kawakami

et al. 2008

Himalayan Journal of Sciences

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“…The South Tibetan Detachment faults form the passive roof fault of the southward extruding Greater Himalayan Sequence partially molten mid-crust during the Early Miocene (c. 23-15 Ma). The South Tibetan Detachment faults have a cumulative geological offset of c. 100 km or more and link north with the folded normal fault detachments that bound the tops of the North Himalayan domes (Lee et al 2000). There is no evidence that these faults are active today, although they must have been at low angles during their Miocene slip, or that they have been rotated from steeper faults (Searle 2010).…”

Section: East-west-aligned Low-angle Normal Faultsmentioning

confidence: 99%

Crustal–lithospheric structure and continental extrusion of Tibet

Searle

Elliott

Phillips

et al. 2011

JGS

231

154

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Crustal shortening and thickening to c. 70-85 km in the Tibetan Plateau occurred both before and mainly after the c. 50 Ma India-Asia collision. Potassic-ultrapotassic shoshonitic and adakitic lavas erupted across the Qiangtang (c. 50-29 Ma) and Lhasa blocks (c. 30-10 Ma) indicate a hot mantle, thick crust and eclogitic root during that period. The progressive northward underthrusting of cold, Indian mantle lithosphere since collision shut off the source in the Lhasa block at c. 10 Ma. Late Miocene-Pleistocene shoshonitic volcanic rocks in northern Tibet require hot mantle. We review the major tectonic processes proposed for Tibet including 'rigid-block', continuum and crustal flow as well as the geological history of the major strikeslip faults. We examine controversies concerning the cumulative geological offsets and the discrepancies between geological, Quaternary and geodetic slip rates. Low present-day slip rates measured from global positioning system and InSAR along the Karakoram and Altyn Tagh Faults in addition to slow long-term geological rates can only account for limited eastward extrusion of Tibet since Mid-Miocene time. We conclude that despite being prominent geomorphological features sometimes with wide mylonite zones, the faults cut earlier formed metamorphic and igneous rocks and show limited offsets. Concentrated strain at the surface is dissipated deeper into wide ductile shear zones.

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“…This antiform has been explained by different mechanisms. [72] express the possibility that the Kangmar dome, one of the North Himalayan gneiss domes located farther east at 91°E, developed above a ramp of the Gyirong-Kangmar thrust, which was active at about 11 Ma. This thrust fault ceases to exist and is not recognized along the traverse of Figure 20; it is therefore indicated as a questionable blind thrust.…”

Section: Himalaya Of Nepalmentioning

confidence: 99%

Thick-Skinned and Thin-Skinned Tectonics: A Global Perspective

Pfiffner¹

2017

Preprint

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This paper gives an overview of the large-scale tectonic styles encountered in orogens worldwide. Thin-skinned and thick-skinned tectonics represents two end member styles recognized in mountain ranges. A thick-skinned tectonic style is typical for margins of continental plates. Thick-skinned style including the entire crust and possibly the lithospheric mantle are associated with intracontinental contraction. Delamination of subducting continental crust and horizontal protrusion of upper plate crust into the opening gap occurs in the terminal stage of continent-continent collision. Continental crust thinned prior to contraction is likely to develop relatively thin thrust sheets of crystalline basement. A true thin-skinned type requires a detachment layer of sufficient thickness. Thickness of the décollement layer as well as the mechanical contrast between décollement layer and detached cover control the style of folding and thrusting within the detached cover units. In subduction related orogens, thin-and thick-skinned deformation may occur several hundreds of kilometers from the plate contact zone. Basin inversion resulting from horizontal contraction may lead to the formation of basement uplifts by the combined reactivation of pre-existing normal faults and initiation of new reverse faults. In composite orogens thick-skinned and thin-skinned structures evolve with a pattern where nappe stacking propagates outward and downward.

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Evolution of the Kangmar Dome, southern Tibet: Structural, petrologic, and thermochronologic constraints

Cited by 269 publications

References 58 publications

The Malashan metamorphic complex in southern Tibet: Dominantly top-to-the north deformation and intrusive origin of its associated granites

The Malashan metamorphic complex in southern Tibet: Dominantly top-to-the north deformation and intrusive origin of its associated granites

Crustal–lithospheric structure and continental extrusion of Tibet

Thick-Skinned and Thin-Skinned Tectonics: A Global Perspective

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