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Journal articles on the topic 'Zanskar (India)'

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Published: 4 June 2021
Last updated: 15 February 2022

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1

SEARLE, MIKE, RICHARD I. CORFIELD, BEN STEPHENSON, and JOE MCCARRON. "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." Geological Magazine 134, no. 3 (May 1997): 297–316. http://dx.doi.org/10.1017/s0016756897006857.

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The collision of India and Asia can be defined as a process that started with the closing of the Tethyan ocean that, during Mesozoic and early Tertiary times, separated the two continental plates. Following initial contact of Indian and Asian continental crust, the Indian plate continued its northward drift into Asia, a process which continues to this day. In the Ladakh–Zanskar Himalaya the youngest marine sediments, both in the Indus suture zone and along the northern continental margin of India, are lowermost Eocene Nummulitic limestones dated at ∼54 Ma. Along the north Indian shelf margin, southwest-facing folded Palaeocene–Lower Eocene shallow-marine limestones unconformably overlie highly deformed Mesozoic shelf carbonates and allochthonous Upper Cretaceous shales, indicating an initial deformation event during the latest Cretaceous–early Palaeocene, corresponding with the timing of obduction of the Spontang ophiolite onto the Indian margin. It is suggested here that all the ophiolites from Oman, along western Pakistan (Bela, Muslim Bagh, Zhob and Waziristan) to the Spontang and Amlang-la ophiolites in the Himalaya were obducted during the late Cretaceous and earliest Palaeocene, prior to the closing of Tethys.The major phase of crustal shortening followed the India–Asia collision producing spectacular folds and thrusts across the Zanskar range. A new structural profile across the Indian continental margin along the Zanskar River gorge is presented here. Four main units are separated by major detachments including both normal faults (e.g. Zanskar, Karsha Detachments), southwest-directed thrusts reactivated as northeast-directed normal faults (e.g. Zangla Detachment), breakback thrusts (e.g. Photoksar Thrust) and late Tertiary backthrusts (e.g. Zanskar Backthrust). The normal faults place younger rocks onto older and separate two units, both showing compressional tectonics, but have no net crustal extension across them. Rather, they are related to rapid exhumation of the structurally lower, middle and deep crustal metamorphic rocks of the High Himalaya along the footwall of the Zanskar Detachment. The backthrusting affects the northern margin of the Zanskar shelf and the entire Indus suture zone, including the mid-Eocene–Miocene post-collisional fluvial and lacustrine molasse sediments (Indus Group), and therefore must be Pliocene–Pleistocene in age. Minimum amounts of crustal shortening across the Indian continental margin are 150–170 km although extreme ductile folding makes any balancing exercise questionable.
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2

Burbank, Douglas W., and Monique B. Fort. "Bedrock Control on Glacial Limits: Examples from the Ladakh and Zanskar Ranges, North-Western Himalaya, India." Journal of Glaciology 31, no. 108 (1985): 143–49. http://dx.doi.org/10.1017/s0022143000006389.

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AbstractIn the north-western Himalaya, the distribution of modem glaciers and snowlines in the Ladakh and Zanskar Ranges adjacent to the Indus River valley suggests comparable climatic conditions prevail in the two ranges. Similarly, the positions of terminal moraines and reconstructed equilibrium-line altitudes (ELAs) indicate equivalent magnitudes of Neoglacial and Late Glacial advances in both ranges. However, the terminal positions and reconstructed ELAs from the late Pleistocene maximum advances are at least 400 m lower in the Ladakh Range than in the nearby Zanskar Range. These differences do not appear to reflect either climatic or tectonic controls. Rather, they are caused by an unusual bedrock configuration in the Zanskar Range, where vertical strata of indurated sandstones and conglomerates, and narrow steep-walled canyons cut through them, created a bulwark that effectively precluded significant down-valley advance. Without recognition of this physical impedance to glacial advance, uncritical reconstructions would greatly overestimate the altitude of the ELA in the Zanskar Range.
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3

Burbank, Douglas W., and Monique B. Fort. "Bedrock Control on Glacial Limits: Examples from the Ladakh and Zanskar Ranges, North-Western Himalaya, India." Journal of Glaciology 31, no. 108 (1985): 143–49. http://dx.doi.org/10.3189/s0022143000006389.

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AbstractIn the north-western Himalaya, the distribution of modem glaciers and snowlines in the Ladakh and Zanskar Ranges adjacent to the Indus River valley suggests comparable climatic conditions prevail in the two ranges. Similarly, the positions of terminal moraines and reconstructed equilibrium-line altitudes (ELAs) indicate equivalent magnitudes of Neoglacial and Late Glacial advances in both ranges. However, the terminal positions and reconstructed ELAs from the late Pleistocene maximum advances are at least 400 m lower in the Ladakh Range than in the nearby Zanskar Range. These differences do not appear to reflect either climatic or tectonic controls. Rather, they are caused by an unusual bedrock configuration in the Zanskar Range, where vertical strata of indurated sandstones and conglomerates, and narrow steep-walled canyons cut through them, created a bulwark that effectively precluded significant down-valley advance. Without recognition of this physical impedance to glacial advance, uncritical reconstructions would greatly overestimate the altitude of the ELA in the Zanskar Range.
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4

Polosmak, N. V., M. A. Shah, and L. P. Kundo. "PETROGLYPHS OF ZANSKAR, INDIA: FINDINGS OF THE 2016 SEASON." Archaeology, Ethnology & Anthropology of Eurasia 46, no. 2 (June 29, 2018): 60–67. http://dx.doi.org/10.17746/1563-0110.2018.46.2.060-067.

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This article introduces new petroglyphs found in 2016 by the Russian-Indian expedition in Zanskar, India. For the fi rst time in this region, we discovered images unilaterally pecked out on small rectangular plates at abandoned Buddhist sanctuaries. Unlike tens of thousands of famous images from Ladakh and Zanskar, these are examples of mobile art, i.e., they could be moved from one place to another. They show scenes of fi ghting wild yaks, a hunter on horseback accompanied by a dog, and a Buddhist stupa. Especially interesting are several kindred scenes reproducing fi ghts between male yaks, which occur in the fall, during the rut. Images realistically and accurately convey a tense atmosphere of rivalry. The image of a horse is unusual. The animal is decorated with a breast tassel and a head plume or sheathed forelock, marking the horseman’s high rank and setting the representation apart from other known images of horses in the petroglyphic art of Ladakh and Zanskar. Very important is the archaic type of stupa, before which the yaks are fi ghting. It provides one of the clues for dating the whole composition, since such types of stupas were built from the 1st century BC onwards. It is proposed that the newly found petroglyphs represent a hitherto unknown tradition of using small specially prepared stone plates.
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5

Polosmak, N. V., M. A. Shah, and L. P. Kundo. "Petroglyphs of Zanskar, India: Findings of the 2016 Season." Archaeology, Ethnology and Anthropology of Eurasia (Russian-language). 46, no. 2 (2018): 60–67. http://dx.doi.org/10.17746/1563-0102.2018.46.2.060-067.

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6

Patel, R. C., Sandeep Singh, A. Asokan, R. M. Manickavasagam, and A. K. Jain. "Extensional tectonics in the Himalayan orogen, Zanskar, NW India." Geological Society, London, Special Publications 74, no. 1 (1993): 445–59. http://dx.doi.org/10.1144/gsl.sp.1993.074.01.30.

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7

Ali, Sheikh Nawaz, Shailesh Agrawal, Anupam Sharma, Binita Phartiyal, Paulramasamy Morthekai, Pawan Govil, Ravi Bhushan, Shazi Farooqui, Partha Sarathi Jena, and Ajay Shivam. "Holocene hydroclimatic variability in the Zanskar Valley, Northwestern Himalaya, India." Quaternary Research 97 (April 30, 2020): 140–56. http://dx.doi.org/10.1017/qua.2020.22.

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AbstractA 1.3-m-long sediment core from the Penzi-la pass, Zanskar Valley, provides a record of hydroclimatic conditions and abrupt climate changes over short time scales since the mid-Holocene. These climatic changes of centennial time scale are crucial to understanding the hydroclimatic variability in northwestern (NW) Himalaya. Relatively higher δ13C values complemented by total organic carbon, loss on ignition, grain size parameters, and lower Rubidium/Strontium ratios during the Late Northgrippian imply that the area had a dry climate during the period from ~6200–4500 cal yr BP. Subsequently, a relatively stable hydroclimatic environment was experienced between ~4500 and 3400 cal yr BP. After ~3400 cal yr BP the multiproxy data show gradual strengthening of hydroclimatic conditions, however, this trend is interrupted by high-amplitude abrupt reversals (dry events) with a stepwise decreasing intensity at ~3300, 2600, 1700, and 400 cal yr BP. The two most important climatic events of the last millennia (i.e., Medieval Climate Anomaly and the Little Ice Age) were also recorded from the sedimentary archive. Overall, our data show a progressive increase in the moisture availability in the Zanskar Valley and are in agreement with the late Holocene climatic trends of central and western Himalaya.
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8

Maheshwari, Aishwarya, A. Arun Kumar, and Sambandam Sathyakumar. "Assessment of changes over a decade in the patterns of livestock depredation by the Himalayan Brown Bear in Ladakh, India." Journal of Threatened Taxa 13, no. 7 (June 26, 2021): 18695–702. http://dx.doi.org/10.11609/jott.7177.13.7.18695-18702.

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Conflicts between large carnivores and shepherds constitute a major socio-ecological concern across the Himalaya and affects community attitudes and tolerance toward carnivores. We assessed the extent and intensity of Human-Brown Bear interactions in the same villages of Zanskar and Suru Valleys, Ladakh, in the Indian Trans-Himalaya during two time periods (2001–2003 and 2009–2012) through field and questionnaire surveys. During 2001–2003, 180 families of 32 villages in Zanskar, and 232 families of 49 villages in Suru were interviewed, and during 2009–2012, 145 families of 23 villages in Zanskar and 115 families of 33 villages in Suru were interviewed. Overall, 475 (119/year) and 454 (151/year) heads of livestock were reportedly killed by Brown Bears. The surveys of 2009–2012 revealed that livestock predation in ‘doksas’ (summer grazing camps) was higher (68 %) compared to the surveys carried out during 2001–2003 (42 %). The increased livestock depredation in doksas might be due to the extended stay and use of pastures by the local communities during spring and autumn. Damage to property in the form of breaking open of doors and windows by Brown Bear were reported during both the surveys. Economic losses and declining tolerance of people may trigger retaliatory killings of Brown Bear in Ladakh. We recommend compensation for livestock loss and improved husbandry practices in the conflict zones for bear-human coexistence.
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9

Corfield, R. I., A. B. Watts, and M. P. Searle. "Subsidence history of the north Indian continental margin, Zanskar–Ladakh Himalaya, NW India." Journal of the Geological Society 162, no. 1 (January 2005): 135–46. http://dx.doi.org/10.1144/0016-764903-162.

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10

Lee, Richard V., Mohamud Daya, Greta Flickinger, and Geshe Ngawang Jangchup. "Tuberculin Testing in a Remote Area of Zanskar Ladakh, India." Journal of Travel Medicine 8, no. 3 (March 8, 2006): 152–53. http://dx.doi.org/10.2310/7060.2001.24465.

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11

Hughes, Nigel C., and Peter A. Jell. "Cambrian trilobite faunas from India: a multivariate and computer-graphic reappraisal and its paleogeographic implications." Paleontological Society Special Publications 6 (1992): 141. http://dx.doi.org/10.1017/s2475262200007012.

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Cambrian trilobite faunas from northern India provide data critical for assessing earliest Phanerozoic paleogeography and for constraining tectonic models of Himalayan evolution. Previous investigations suggest that Indian Middle Cambrian trilobite faunas, collected from basins 500 km apart, are strikingly different. The Kashmir fauna, in the west, shows supposed faunal affinities with northern China, while the Spiti fauna, in the east, was considered of European affinity. This counterintuitive faunal distribution in adjacent basins might suggest that the area was made up of several micro-contininents during Cambrian time. Although frequently neglected, this interpretation has major implications for models of Himalayan mountain building, as most models assume a passive northern margin of India throughout the Phanerozoic.Original type material from Kashmir and Spiti and fresh collections from intermediate localities in the Zanskar valley have been evaluated using a new statistical/computer-graphic method which removes the effects of tectonic deformation. Results show that the supposed taxonomic distinctness of the Kashmiri and Spiti faunas is largely superficial. Previous lack of appreciation of deformation has lead to: 1. over-estimation of the number of taxa present; 2. misidentification of many taxa; 3. spurious correlations with other faunas; 4. inaccurate age estimates. The revised assessment indicates that: 1. approximately 12 species of polymerid trilobites are present in the Middle Cambrian of north India; 2. 3 polymerid trilobite species are common to both Kashmir and Spiti faunas; 3. much of the Spiti fauna is significantly older than the Kashmiri fauna; 4. faunal differences between coeval deposits from the two basins are best explained as biofacies differences related to an offshore proximality trend; 5. species show patterns of developmental flexibility similar to that recently reported in other Cambrian trilobites. The faunas do not suggest that Kashmir and Spiti were part of separate continents during the Cambrian.The morphology of Middle Cambrian faunas from Kashmir, Zanskar and Spiti suggests that all polymerid species were benthic and share morphotypes characteristic of trilobites from slope environments. Lithologic evidence suggesting that Kashmiri faunas were deeper water than those from Spiti is complimented by the presence in Kashmir of the atheloptic trilobite Bailiella, which is characteristic of deeper waters. Faunas from Kashmir, Zanskar and Spiti, which lie within the Tethyan belt of the Indian Himalaya, share closest affinity with those described from north China, north Vietnam and south China. They also show affinity with faunas from Iran. This pattern is consistent with recent paleogeographic reconstructions which place these regions in close proximity and at similar latitudes. Most of the Cambrian within the Tethyan Himalaya is of middle Middle Cambrian age.The recognition of developmental flexibility as a general characteristic of Cambrian trilobites suggests many groups may be taxonomically over-split. Over-splitting may have lead to widespread over-estimation of faunal provinciality during Cambrian times.
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12

POGNANTE, U., and B. LOMBARDO. "Metamorphic evolution of the High Himalayan Crystallines in SE Zanskar, India." Journal of Metamorphic Geology 7, no. 1 (January 1989): 9–17. http://dx.doi.org/10.1111/j.1525-1314.1989.tb00571.x.

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13

Rai, Praveen Kumar, M. S. Nathawat, and Kshitij Mohan. "Glacier Retreat in Doda Valley, Zanskar Basin, Jammu & Kashmir, India." Universal Journal of Geoscience 1, no. 3 (December 2013): 139–49. http://dx.doi.org/10.13189/ujg.2013.010304.

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14

Herren, Eveline. "Zanskar shear zone: Northeast-southwest extension within the Higher Himalayas (Ladakh, India)." Geology 15, no. 5 (1987): 409. http://dx.doi.org/10.1130/0091-7613(1987)15<409:zsznew>2.0.co;2.

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15

Collette, Joseph H., Nigel C. Hughes, and Shanchi Peng. "The first report of a Himalayan bradoriid arthropod and the paleogeographic significance of this form." Journal of Paleontology 85, no. 1 (January 2011): 76–82. http://dx.doi.org/10.1666/10-063.1.

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Two arthropod specimens assigned to Anabarochilina australis (Hinz-Schallreuter, 1993) from the late middle Cambrian (Guzhangian Stage, Lejopyge acantha Biozone) Karsha Formation, Zanskar Valley, northern India comprise the first record of the Bradoriida from the Himalaya. These Indian specimens cannot be distinguished statistically from other A. australis material based on valve length and height ratios, and differ only slightly in other characters. These observations justify the synonymy of a number of similar forms worldwide that previously have been only questionably attributed to A. australis. The occurrence of the species in Australia, India, Laurentia, and Kazakhstan encompassed an equatorial distribution from approximately 20° north to 20° south during late middle Cambrian time and indicates that A. australis had the ability to disperse across deep ocean basins. Such a distribution is consistent with a planktonic lifestyle. In contrast, other congeneric species of Anabarochilina apparently had more localized occurrence or, in the case of A. primordialis, were distributed across several paleocontinents and climatic zones.
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16

Parcha, S. K., and Birendra P. Singh. "Stratigraphic significance of the Cambrian ichnofauna of the Zanskar region, Ladakh Himalaya, India." Journal of the Geological Society of India 75, no. 3 (March 2010): 503–17. http://dx.doi.org/10.1007/s12594-010-0040-x.

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17

Taloor, Ajay Kumar, Girish Chandra Kothyari, Drinder Singh Manhas, Harish Bisht, Pankaj Mehta, Meenakshi Sharma, Sugandha Mahajan, Sagarika Roy, Anil Kumar Singh, and Sajid Ali. "Spatio-temporal changes in the Machoi glacier Zanskar Himalaya India using geospatial technology." Quaternary Science Advances 4 (October 2021): 100031. http://dx.doi.org/10.1016/j.qsa.2021.100031.

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18

Niranjan, Saket Kumar, Ranjit S. Kataria, Monika Sodhi, Vijay K. Bharti, Bhuvnesh Kumar, Ajay Garg, M. C. Pandey, Ankita Sharma, Prince Vivek, and Arup Giri. "Evaluation of Physiological Parameters in Response to Endurance Exercise of Zanskar Ponies Adapted to High Altitude of Ladakh Region." Defence Life Science Journal 3, no. 2 (March 23, 2018): 172. http://dx.doi.org/10.14429/dlsj.3.12573.

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Zanskar pony, a native horse breed of Ladakh mainly used for transportation in Trans-Himalayan region of India, is well adapted to high altitude hypobaric hypoxia environment. Due to extreme conditions of the Ladakh region, better endurance of these ponies under hypoxic and extreme cold conditions is of utmost concern for their recruitment in Indian Army. In the present study, 12 young trained Zanskar ponies were evaluated during endurance exercise at an altitude of 3292 meter above mean sea level. The animals were subjected to carriage transport with 65-70Kg load or riding on a track of 5-6 Km. Physiological parameters <em>viz</em>., pulse rate (PR), heart rate (HR), rectal temperature (RT), respiratory rate (RR) and oxygen saturation (SaO<sub>2</sub>) were recorded in Zanskar ponies during pre-exercise (T<sub>0</sub>), post- exercise (T<sub>1</sub>) and post recovery (T<sub>2, </sub>2 hours post resting) stages. Results showed marked increase in PR, HR, RR and RT post exercise time points. The mean values of PR increased from 49.83±4.62 to 73.67±21.54 per minute, HR from 48±13.60 to 75±15.82 beats/min, RR from 37.83±9.70 to 57.67±13.48 per min and RT from 99.62±0.34 101.04±0.53 °F from pre stress to post endurance stress. The mean SaO<sub>2 </sub>level reduced significantly (88.58±6.75 at T<sub>0</sub> versus 64.00±18.70 at T<sub>1</sub> and 54.42±14.79 at T<sub>2</sub>) post exercise. This indicated limited availability of arterial oxygen for tissues which could be vital factor for adverse change in some of physio-biochemical parameters. Though the trend of physiological response was similar for all the 12 animals, still variation at individual animal level was observed during endurance stress. In future, some of these physiological parameters along with biochemical and molecular parameters could be evaluated as potential biomarkers in selecting ponies with superior endurance trait specifically under hypoxic conditions.
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19

Peng, Shanchi, Nigel C. Hughes, Noel A. Heim, Bryan K. Sell, Xuejian Zhu, Paul M. Myrow, and Suraj K. Parcha. "Cambrian Trilobites from the Parahio and Zanskar Valleys, Indian Himalaya." Journal of Paleontology 83, S71 (November 2009): 1–95. http://dx.doi.org/10.1666/08-129.1.

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New collections of trilobites from the type section of the Parahio Formation in the Parahio Valley, Spiti, and from the Parahio, Karsha, and Kurgiakh formations in the Zanskar Valley, permit biozonation based on material precisely located within measured stratigraphic sections. Specimens preserved in limestone with mild tectonic deformation clarify the features of several Himalayan taxa known previously only from severely deformed specimens preserved in shale. A total of 75 trilobite taxa from the Cambrian of Spiti and Zanskar can be referred, questionably at least, at the generic level or below, and 61 of these are present in our new collections. This new material is assigned with confidence to 29 existing species, and to 12 new species. Three new genera,Haydenaspis, Bhargavia, andHimalisania, are established; new species includeHaydenaspis parvatya, Prozacanthoides lahiri, Probowmania bhatti, Xingrenaspis parthiva, X. shyamalae, Bhargavia prakritika, Kaotaia prachina, Gunnia smithi, Sudanamonocarina sinindica, Proasaphiscus simoni, Koldinia odelli, andTorifera jelli. Ten additional Himalayan forms are assigned at the generic level only, and another 11 are questionably assigned to genera or species. The zonation proposed includes 6 zones and 3 levels, including theHaydenaspis parvatyalevel, theOryctocephalus indicuslevel, theKaotaia prachinaZone, theParamecephalus defossusZone, theOryctocephalus salteriZone, theIranoleesia buteslevel, theSudanomocarina sinindicaZone, theLejopyge acanthaZone, and theProagnostus bulbusZone. The sections span from the upper part of the informal Stage 4, Series 2 of the Cambrian System, about 511 Ma old, to theProagnostus bulbuszone of the Guzhangian Stage near the top of Series 3, dated at about 501 Ma. This time interval is represented by about 2000 m of section, which is thick compared to similar intervals elsewhere and is consistent with high rates of sedimentation along the Himalayan margin at the time. The fauna resembles others from equatorial peri-Gondwanaland, with closest similarity to that of South China. It also bears strong affinity to the North China fauna. Juvenile trilobites are described for the first time from India. A new Chinese species,Monanocephalus liquani, is also described.
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20

Nonzom, Skarma, and Geeta Sumbali. "New Record of Chaetasbolisia erysiphoides from Cold Arid Soils of Zanskar (Kargil), India." Current Science 114, no. 01 (January 10, 2018): 25. http://dx.doi.org/10.18520/cs/v114/i01/25-27.

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21

Clift, Peter D., Andrew Carter, and Tara N. Jonell. "U–Pb dating of detrital zircon grains in the Paleocene Stumpata Formation, Tethyan Himalaya, Zanskar, India." Journal of Asian Earth Sciences 82 (March 2014): 80–89. http://dx.doi.org/10.1016/j.jseaes.2013.12.014.

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22

Vance, D. "Ar-Ar Constraints on Erosional Versus Extensional Unroofing in Orogenic Belts: The Zanskar Himalaya, NW India." Mineralogical Magazine 58A, no. 2 (1994): 930–31. http://dx.doi.org/10.1180/minmag.1994.58a.2.219.

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23

Orr, Elizabeth N., Lewis A. Owen, Madhav K. Murari, Sourav Saha, and Marc W. Caffee. "The timing and extent of Quaternary glaciation of Stok, northern Zanskar Range, Transhimalaya, of northern India." Geomorphology 284 (May 2017): 142–55. http://dx.doi.org/10.1016/j.geomorph.2016.05.031.

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24

Chan, M., W. Tsai, and M. Dai. "Hypertension prevalence in Zanskar, India: a study to guide future health interventions in rural health clinics." Annals of Global Health 82, no. 3 (August 20, 2016): 409. http://dx.doi.org/10.1016/j.aogh.2016.04.142.

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25

Dyck, Brendan, Marc St-Onge, Michael P. Searle, Nicole Rayner, David Waters, and Owen M. Weller. "Protolith lithostratigraphy of the Greater Himalayan Series in Langtang, Nepal: implications for the architecture of the northern Indian margin." Geological Society, London, Special Publications 483, no. 1 (September 20, 2018): 281–304. http://dx.doi.org/10.1144/sp483.9.

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AbstractReconstruction of the protolith lithostratigraphy of amphibolite-facies metasedimentary rocks of the Greater Himalayan Series (GHS) in Nepal documents a single, long-lived passive-margin succession that was deposited along the northern margin of the Indian Craton. In the Langtang area, Paleoproterozoic gneisses are unconformably overlain by a succession of upper Neoproterozoic–Ordovician fluvio-deltaic quartzite, basinal pelite and psammitic beds that grade upsection into micaceous semipelite and pelite. U–Pb zircon geochronology yields maximum depositional ages between c. 815 and 460 Ma for the GHS in Langtang. Regional variations in the composition and thickness of the GHS along the length of the Himalaya are attributed to siliciclastic depocentres centred on Zanskar in northern India, Langtang and Everest in central to western Nepal, which contrast with coeval marine carbonate shelf deposition in the Annapurna region. The protolith lithostratigraphy documented for Langtang provides a coherent framework for interpreting subsequent Cenozoic Himalayan deformation, specifically the homogeneously distributed layer-normal shortening (i.e. flattening) and layer-parallel stretching (i.e. transport-parallel stretching) that characterizes the GHS. Within the context of a single protracted northern Indian marginal sedimentary succession, the distinction between the Lesser, Greater and Tethyan Himalaya is structural rather than lithostratigraphic in origin.
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26

KUNDIG, R. "Domal structures and high-grade metamorphism in the Higher Himalayan Crystalline, Zanskar Region, north-west Himalaya, India." Journal of Metamorphic Geology 7, no. 1 (January 1989): 43–55. http://dx.doi.org/10.1111/j.1525-1314.1989.tb00574.x.

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27

Garzanti, E., R. Haas, and F. Jadoul. "Ironstones in the Mesozoic passive margin sequence of the Tethys Himalaya (Zanskar, Northern India): sedimentology and metamorphism." Geological Society, London, Special Publications 46, no. 1 (1989): 229–44. http://dx.doi.org/10.1144/gsl.sp.1989.046.01.20.

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28

Vannay, J. C., and L. Spring. "Geochemistry of the continental basalts within the Tethyan Himalaya of Lahul-Spiti and SE Zanskar, northwest India." Geological Society, London, Special Publications 74, no. 1 (1993): 237–49. http://dx.doi.org/10.1144/gsl.sp.1993.074.01.17.

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29

Ghosh, Swagata, A. C. Pandey, M. S. Nathawat, I. M. Bahuguna, and Ajai. "Contrasting Signals of Glacier Changes in Zanskar Valley, Jammu & Kashmir, India Using Remote Sensing and GIS." Journal of the Indian Society of Remote Sensing 42, no. 4 (May 14, 2014): 817–27. http://dx.doi.org/10.1007/s12524-014-0368-6.

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30

Garzanti, E., D. Sciunnach, M. Gaetani, R. I. Corfield, A. B. Watts, and M. P. Searle. "Discussion on subsidence history of the north Indian continental margin, Zanskar–Ladakh Himalaya, NW India Journal, Vol. 162, 2005, pp. 135–146." Journal of the Geological Society 162, no. 5 (September 2005): 889–92. http://dx.doi.org/10.1144/0016-764905-011.

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31

Taloor, Ajay Kumar, Bahadur Singh Kotlia, Avtar Singh Jasrotia, Ajay Kumar, Akhtar Alam, Sadiq Ali, Beena Kouser, et al. "Tectono-climatic influence on landscape changes in the glaciated Durung Drung basin, Zanskar Himalaya, India: A geospatial approach." Quaternary International 507 (February 2019): 262–73. http://dx.doi.org/10.1016/j.quaint.2018.09.030.

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32

Govindha Raj, K. Babu. "Remote sensing based hazard assessment of glacial lakes: a case study in Zanskar basin, Jammu and Kashmir, India." Geomatics, Natural Hazards and Risk 1, no. 4 (December 2010): 339–47. http://dx.doi.org/10.1080/19475705.2010.532973.

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33

Jonell, Tara N., Andrew Carter, Philipp Böning, Katharina Pahnke, and Peter D. Clift. "Climatic and glacial impact on erosion patterns and sediment provenance in the Himalayan rain shadow, Zanskar River, NW India." Geological Society of America Bulletin 129, no. 7-8 (April 28, 2017): 820–36. http://dx.doi.org/10.1130/b31573.1.

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34

Chauvet, François, Henriette Lapierre, Delphine Bosch, Stéphane Guillot, Georges Mascle, Jean-Claude Vannay, Jo Cotten, Pierre Brunet, and Francine Keller. "Geochemistry of the Panjal Traps basalts (NW Himalaya): records of the Pangea Permian break-up." Bulletin de la Société Géologique de France 179, no. 4 (July 1, 2008): 383–95. http://dx.doi.org/10.2113/gssgfbull.179.4.383.

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AbstractThe late Lower to Middle Permian Panjal Traps (NW Himalaya, India-Pakistan) represent the greatest magmatic province erupted on the northern Indian platform during the Neotethys opening. New geochemical and isotopic analyses were performed on basalts from the eastern borders of the traps (SE Zanskar-NW Spiti area) in order to characterize this volcanism, to discuss its compositional variations in comparison to Panjal counterparts and its relationships with the opening of Neotethys. Lavas show features of tholeiitic low-Ti (&lt; 1.6%) continental flood basalts with LREE, Th enrichments and Nb-Ta negative anomalies. Trace element ratios combined with εNdi values (−3.6 to +0.9) and high Pb isotopic ratios suggest that these tholeiitic basalts were derived from an OIB-like mantle contaminated at various degrees by a continental crust component. Previous geochemical features are broadly similar to those of the coeval Panjal volcanic sequences identified westwards (Ladakh, Kashmir and Pakistan). Present geochemical constraints obtained for the Panjal Traps basalts suggest they originated from rapid effusion of tholeiitic melts during opening of the Neotethys Ocean. Similar magmatism implying an OIB-type reservoir is contemporaneously recognized on and along the adjacent Arabian platform. Both Indian and Arabian Permian volcanics were emplaced during coeval syn-rift to post rift transition. These Lower to Middle Permian south Neotethyan continental flood magmatism are regarded as associated to a passive rifting. In this scheme, OIB-type isotopic signature would be related either to a melting episode of syn-rift up-welling mantle plumes or to a melting of a regional abnormally hot and enriched mantle.
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Noble, S. R., and M. P. Searle. "Age of crustal melting and leucogranite formation from U-Pb zircon and monazite dating in the western Himalaya, Zanskar, India." Geology 23, no. 12 (1995): 1135. http://dx.doi.org/10.1130/0091-7613(1995)023<1135:aocmal>2.3.co;2.

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36

Jonell, Tara N., Andrew Carter, Philipp Böning, Katharina Pahnke, and Peter D. Clift. "ERRATUM: Climatic and glacial impact on erosion patterns and sediment provenance in the Himalayan rain shadow, Zanskar River, NW India." GSA Bulletin 131, no. 3-4 (March 1, 2019): 704. http://dx.doi.org/10.1130/b31573e.1.

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37

Martha, Tapas R., P. Shashivardhan Reddy, C. M. Bhatt, K. Babu Govindha Raj, J. Nalini, E. Anantha Padmanabha, B. Narender, et al. "Debris volume estimation and monitoring of Phuktal river landslide-dammed lake in the Zanskar Himalayas, India using Cartosat-2 images." Landslides 14, no. 1 (August 26, 2016): 373–83. http://dx.doi.org/10.1007/s10346-016-0749-8.

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38

Vance, Derek, and Emma Mahar. "Pressure-temperature paths from P - T pseudosections and zoned garnets: potential, limitations and examples from the Zanskar Himalaya, NW India." Contributions to Mineralogy and Petrology 132, no. 3 (August 28, 1998): 225–45. http://dx.doi.org/10.1007/s004100050419.

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39

Pognante, U., D. Castelli, P. Benna, G. Genovese, F. Oberli, M. Meier, and S. Tonarini. "The crystalline units of the High Himalayas in the Lahul–Zanskar region (northwest India): metamorphic–tectonic history and geochronology of the collided and imbricated Indian plate." Geological Magazine 127, no. 2 (March 1990): 101–16. http://dx.doi.org/10.1017/s0016756800013807.

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AbstractIn the High Himalayan belt of northwest India, crustal thickening linked to Palaeogene collision between India and Eurasia has led to the formation of two main crystalline tectonic units separated by the syn-metamorphic Miyar Thrust: the High Himalayan Crystallines sensu stricto (HHC) at the bottom, and the Kade Unit at the top. These units are structurally interposed between the underlying Lesser Himalaya and the very low-grade sediments of the Tibetan nappes. They consist of paragneisses, orthogneisses, minor metabasics and, chiefly in the HHC, leucogranites. The HHC registers: a polyphase metamorphism with two main stages designated as M1 and M2; a metamorphic zonation with high-temperature recrystallization and migmatization at middle structural levels and medium-temperature assemblages at upper and lower levels. In contrast, the Kade Unit underwent a low-temperature metamorphism. Rb–Sr and U–Th–Pb isotope data point to derivation of the orthogneisses from early Palaeozoic granitoids, while the leucogranites formed by anatexis of the HHC rocks and were probably emplaced during Miocene time.Most of the complicated metamorphic setting is related to polyphase tectonic stacking of the HHC with the ‘cooler’ Kade Unit and Lesser Himalaya during the Himalayan history. However, a few inconsistencies exist for a purely Himalayan age of some Ml assemblages of the HHC. As regards the crustal-derived leucogranites, the formation of a first generation mixed with quartzo-feldspathic leucosomes was possibly linked to melt-lubricated shear zones which favoured rapid crustal displacements; at upper levels they intruded during stage M2 and the latest movements along the syn-metamorphic Miyar Thrust, but before juxtaposition of the Tibetan nappes along the late- metamorphic Zanskar Fault.
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40

Paulsen, Timothy S., Christie M. Demosthenous, Paul M. Myrow, Nigel C. Hughes, and S. K. Parcha. "Paleostrain stratigraphic analysis of calcite twins across the Cambrian–Ordovician unconformity in the Tethyan Himalaya, Spiti and Zanskar valley regions, India." Journal of Asian Earth Sciences 31, no. 1 (August 2007): 44–54. http://dx.doi.org/10.1016/j.jseaes.2007.04.001.

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41

Dietsch, Craig, Kathryn Hedrick, Lewis A. Owen, and Marc W. Caffee. "Tracking denudation and sediment production and transport with cosmogenic 10 Be in arid, high‐altitude Himalayan half‐grabens, Zanskar, northern India." Earth Surface Processes and Landforms 45, no. 13 (August 3, 2020): 3103–19. http://dx.doi.org/10.1002/esp.4954.

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42

HUGHES, NIGEL C., SHANCHI PENG, O. N. BHARGAVA, A. D. AHLUWALIA, SANDEEP WALIA, PAUL M. MYROW, and S. K. PARCHA. "Cambrian biostratigraphy of the Tal Group, Lesser Himalaya, India, and early Tsanglangpuan (late early Cambrian) trilobites from the Nigali Dhar syncline." Geological Magazine 142, no. 1 (January 2005): 57–80. http://dx.doi.org/10.1017/s0016756804000366.

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Precise biostratigraphic constraints on the age of the Tal Group are restricted to (1) a basal level correlative with the Anabarites trisulcatus–Protohertzina anabarica Assemblage Zone of southwest China, (2) a level near the boundary of the lower and upper parts of the Tal Group correlative with the early Tsanglangpuan Stage (Drepanuroides Zone), and (3) an interval low in the upper part of the Tal Group correlative with later in the Tsanglangpuan Stage (Palaeolenus Zone). These correlations are based on small shelly fossil and trilobite taxa. Other chronostratigraphic constraints include the marked negative δ13C isotopic excursion coincident with the transition from the Krol Group to the Tal Group. This excursion is used as a proxy for the Precambrian–Cambrian boundary in several sections worldwide and, if applied to the Lesser Himalaya, indicates that the boundary is at or just above the base of the Tal Group. The upper parts of the Tal Group may be of middle or late Cambrian age and might form proximal equivalents of sections in the Zanskar–Spiti region of the Tethyan Himalaya. Both faunal content and lithological succession are comparable to southwest China, furthering recent arguments for close geographic proximity between the Himalaya and the Yangtze block during late Neoproterozoic and early Cambrian time. Trilobites from the uppermost parts of the Sankholi Formation from the Nigali Dhar syncline are described and referred to three taxa, one of which, Drepanopyge gopeni, is a new species. They are the oldest trilobites yet described from the Himalaya.
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43

Garzanti, Eduardo. "Sedimentary evolution and drowning of a passive margin shelf (Giumal Group; Zanskar Tethys Himalaya, India): palaeoenvironmental changes during final break-up of Gondwanaland." Geological Society, London, Special Publications 74, no. 1 (1993): 277–98. http://dx.doi.org/10.1144/gsl.sp.1993.074.01.20.

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44

Pognante, U. "Migmatites and Leucogranites of tertiary age from the high Himalayan Crystallines of Zanskar (NW India): a case history of anatexis of Palaeozoic orthogneisses." Mineralogy and Petrology 46, no. 4 (1992): 291–313. http://dx.doi.org/10.1007/bf01173569.

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45

Ayres, Michael, Nigel Harris, and Derek Vance. "Possible constraints on anatectic melt residence times from accessory mineral dissolution rates: an example from Himalayan leucogranites." Mineralogical Magazine 61, no. 404 (February 1997): 29–36. http://dx.doi.org/10.1180/minmag.1997.061.404.04.

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AbstractThe concentrations of LREE and Zr in a granitic melt formed by anatexis of a metapelitic protolith will be buffered by the stability of monazite and zircon respectively. The rate at which equilibrium is reached between dissolving monazite and zircon and a static melt is limited by the rate at which Zr and LREE can diffuse away from dissolution sites. If melt extraction rates exceed the rates at which the LREE and Zr in the melt become homogenized by diffusion, extracted melts will be undersaturated with respect to these elements. Evidence from accessory phase thermometry suggests that for many Himalayan leucogranites generated by crustal anatexis, the melts equilibrated with restitic monazite and zircon prior to extraction. In contrast, discordant temperatures determined from accessory phase thermometry suggest that tourmaline leucogranites from the Zanskar region of NW India did not equilibrate prior to extraction. Quantitative interpretation of this discordance assumes that the melt was static prior to extraction, and that accessory phase inheritance was minimal. Modelling of the time-dependant homogenization process suggests that tourmaline leucogranites generated at 700°C probably remained in contact with restitic monazite in the protolith for less than 7 ka and certainly less than 50 ka. Such rapid extraction rates suggest that deformation-driven mechanisms were important in removing these melts from their source.
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Taloor, Ajay Kumar, Bahadur Singh Kotlia, Avtar Singh Jasrotia, Ajay Kumar, Akhtar Alam, Sadiq Ali, Beena Kouser, et al. "Corrigendum to “Tectono-climatic influence on landscape changes in the glaciated Durung Drung basin, Zanskar Himalaya, India: A geospatial approach” [Quat. Int. 507(2019) 262–273]." Quaternary International 522 (July 2019): 120. http://dx.doi.org/10.1016/j.quaint.2019.05.022.

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47

Goswami-Banerjee, S., and M. Robyr. "Pressure and temperature conditions for crystallization of metamorphic allanite and monazite in metapelites: a case study from the Miyar Valley (high Himalayan Crystalline of Zanskar, NW India)." Journal of Metamorphic Geology 33, no. 5 (May 14, 2015): 535–56. http://dx.doi.org/10.1111/jmg.12133.

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48

Virmani, Nancy, Birendra P. Singh, and Aman Gill. "Integrated litho-ichnofacies and ichnofabric analysis of the lowermost part of the Kunzum La Formation along the Khemangar khad and the Parahio Valley sections, Spiti Region (Zanskar-Spiti-Kinnaur Basin), Northwest Himalaya, India)." Journal of the Geological Society of India 85, no. 5 (May 2015): 557–66. http://dx.doi.org/10.1007/s12594-015-0250-3.

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49

Taylor, Peter J., and Wishart A. Mitchell. "The Quaternary glacial history of the Zanskar Range, north-west Indian Himalaya." Quaternary International 65-66 (April 2000): 81–99. http://dx.doi.org/10.1016/s1040-6182(99)00038-5.

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50

Myrow, P. M., K. E. Snell, N. C. Hughes, T. S. Paulsen, N. A. Heim, and S. K. Parcha. "Cambrian Depositional History of the Zanskar Valley Region of the Indian Himalaya: Tectonic Implications." Journal of Sedimentary Research 76, no. 2 (February 1, 2006): 364–81. http://dx.doi.org/10.2110/jsr.2006.020.

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