Structure of the North Indian continental margin in the 

Ladakh–Zanskar Himalayas: implications for the timing of 

obduction of the Spontang ophiolite, India–Asia collision and 

deformation events in the Himalaya

Searle, Mike; Corfield, Richard; Stephenson, Ben; McCarron, Joe J.

doi:10.1017/s0016756897006857

Cited by 226 publications

(149 citation statements)

References 2 publications

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“…We define the final India-Asia collision as the timing of the final marine sedimentation (planktonic foraminifera zone P8; shallow benthic zone SBZ10; Green et al 2008) in the suture zone and along the north Indian plate margin (Garzanti et al 1987;Searle et al 1988Searle et al , 1997bRowley 1998;Zhu et al 2005;Green et al 2008). Ophiolite obduction southward onto the passive margin of Indian preceded India-Asia collision and most probably occurred during the Late Cretaceous-Palaeocene (Searle et al 1988(Searle et al , 1997b.…”

Section: Pre-collision Thickeningmentioning

confidence: 99%

“…Kongur, Muztagh Ata) are not offset across the fault (Robinson et al 2007;Robinson 2009a,b). The southeastern end of the Karakoram Fault merges into the Indus-Yarlung Tsangpo suture zone south of Mount Kailas, where north-directed backthrusting occurs along the northern margin of the Indian plate (Searle 1996;Searle et al 1997b) and north-south extensional faulting occurs in the Purang graben (Murphy et al 2000;Murphy & Yin 2003). The Karakoram Fault forms one major strand along the Nubra Valley but in the Tangtse region the fault splays into two branches, the main strand, the Tangtse Fault strand, to the SW and the Pangong Fault strand to the NE, both of which display spectacular mylonites (Fig.…”

Section: Karakoram Faultmentioning

confidence: 99%

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Crustal–lithospheric structure and continental extrusion of Tibet

Searle

Elliott

Phillips

et al. 2011

JGS

240

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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Section: Pre-collision Thickeningmentioning

confidence: 99%

Section: Karakoram Faultmentioning

confidence: 99%

Crustal–lithospheric structure and continental extrusion of Tibet

Searle

Elliott

Phillips

et al. 2011

JGS

240

154

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show abstract

“…Prior to the India-Asia collision, India's northern continental periphery was a passive margin of the Tethys Ocean, with late Permian and Mesozoic shelf carbonates deposited over Pennian volcanics and Palaeozoic sediments (Searle et aI., 1997). During the Cretaceous, ophiolite slabs were obducted from the margins of the Tethys basin (Searle, 1983;Sinha, 1992;Osmaston, 1994;Searle et al, 1997) and the fore-arc basin of the Dras island arc was closed. Northward subduction of Mesozoic oceanic crust created an Andean style destructive plate margin and the emplacement of the Trans-Himalayan granite batholith (1 in Fig.…”

Section: Geological Evolution Of the North-western Himalayamentioning

confidence: 99%

The Quaternary glacial history of the Zanskar Range, north-west Indian Himalaya

Taylor

2000

Quaternary International

102

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“…These formations could not be traced to the east of Ladakh sector in Lhasa and southern Tibet region and remain a peculiarity of the northwestern Himalaya. However, tectonic models proposing two subduction zones in general assume two sutures along the entire south Asian boundary (Brookfield and Reynolds, 1981;Rai, 1983;Reynolds et al, 1983;Coward and Butler, 1985;Petterson and Windley, 1985;Srimal, 1986;Sharma, 1987;Treloar et al, 1989;Searle et al, 1997;Weinberg and Dunlap, 2000;Dunlap and Wysoczanski, 2002;Robertson and Collins, 2002;Dubois-Cote et al, 2005;Dupuis et al, 2005). This has resulted in various attempts of correlating older sutures present in Lhasa-Tibet block with the Shyok suture (Dunlap and Wysoczanski, 2002;Lacassin et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

“…Brookfield and Reynolds (1981), and Reynolds et al (1983) suggested that the Shyok suture closed in Miocene after the Late Cretaceous suturing along the Indus suture. However, Coward and Butler (1985), Petterson and Windley (1985), Treloar et al (1989) and Searle et al (1997) proposed that the Shyok suture is older than the Indus suture. Rai (1983) reported upper Cretaceous to Eocene marine fossils from the flysch of the Shyok suture zone.…”

Section: Introductionmentioning

confidence: 99%