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Geochemical and metamorphic record of the amphibolites from the Tuting–Tidding Suture Zone ophiolites, Eastern Himalaya, India: implications for the presence of a dismembered metamorphic sole

Published online by Cambridge University Press:  29 September 2020

Amrita Dutt*
Affiliation:
Wadia Institute of Himalayan Geology, Dehradun, 248001, India
A Krishnakanta Singh
Affiliation:
Wadia Institute of Himalayan Geology, Dehradun, 248001, India
Rajesh K Srivastava
Affiliation:
Department of Geology, Banaras Hindu University, Varanasi, 221005, India
Govind Oinam
Affiliation:
Wadia Institute of Himalayan Geology, Dehradun, 248001, India
RK Bikramaditya
Affiliation:
Department of Geology, Banaras Hindu University, Varanasi, 221005, India
*
*Author for correspondence: Amrita Dutt, Email: [email protected]

Abstract

The Tuting–Tidding Suture Zone (TTSZ), exposed along Dibang and Lohit river valleys in Arunachal Himalaya, NE India, is the easternmost continuation of the Indus–Tsangpo Suture Zone (ITSZ) and consists of ophiolites associated with metabasics and carbonates. Amphibolites, existing at the base of the ophiolite complex, were studied using whole-rock, mineral chemical analyses and pressure–temperature (P-T) pseudosection modelling to understand their metamorphic and petrogenetic history, and interpret the tectonic environment of their formation. They exhibit two-stage deformation, where D1 is depicted by polymineralic inclusion trails in former melt pools and the main foliation represents D2. Sub-alkaline tholeiitic character, high-field-strength element (HFSE) ratios and mid-oceanic ridge basalt (MORB) -like rare earth element (REE) patterns with negative Eu anomaly indicate that the protolith of these amphibolites originated in a spreading regime by extensive partial melting of a depleted mantle source at shallow depth. Petrography, mineral chemistry and P-T modelling indicate a three-stage metamorphic history for them. M1 is the prograde (c. 2.1 GPa, c. 450°C) defined by garnet centre compositions corresponding to the D1 event. The existence of former melts in the samples demarcates the M2 stage (1.4–1.8 GPa, c. 600°C). The rocks later underwent retrogression (M3: 0.8–1.0 GPa, 480–520°C), which corresponds to the D2 event. These observations suggest that the protolith of the TTSZ amphibolites originated in a mid-oceanic ridge setting, which accreted below a subduction zone where it underwent M1 metamorphism followed by M2 metamorphism, corresponding to partial melting of the rocks. Finally, the M3 event occurred during the obduction phase of the ophiolite complex, where the amphibolites were obducted as the metamorphic sole of the TTSZ ophiolites.

Type
Original Article
Copyright
© The Author(s), 2020. Published by Cambridge University Press

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References

Acharyya, SK (1987) Cenozoic plate motions creating the Eastern Himalaya and Indo-Burmese range around the northeast corner of India. In Ophiolites and Indian Plate Margins (eds Ghosh, NC, Varadarajan, S), pp. 143–60. Patna: Patna University.Google Scholar
Ahmad, T, Tanaka, T, Sachan, HK, Asahara, Y, Islam, R and Khanna, PP (2008) Geochemical and isotopic constraints on the age and origin of the Nidar Ophiolitic Complex, Ladakh, India: implications for the Neo-Tethyan subduction along the Indus suture zone. Tectonophysics 451, 206–24.CrossRefGoogle Scholar
Aitchison, JC, Xia, X, Baxter, AT and Ali, JR (2011) Detrital zircon U–Pb ages along the Yarlung-Tsangpo suture zone, Tibet: implications for oblique convergence and collision between India and Asia. Gondwana Research 20, 691709.CrossRefGoogle Scholar
Aldanmaz, E (2002) Mantle source characteristics of alkali basalts and basanites in an extensional intracontinental plate setting, western Anatolia, Turkey: implications for multi-stage melting. International Geology Review 44, 440–57.CrossRefGoogle Scholar
Aldanmaz, E, Yaliniz, MK, Güctekin, A and Göncüoğlu, MC (2008) Geochemical characteristics of mafic lavas from the Neotethyan ophiolites in western Turkey: implications for heterogeneous source contribution during variable stages of ocean crust generation. Geological Magazine 145, 3754.CrossRefGoogle Scholar
Allegre, CO, Courtillot, V, Tapponnier, P, Hirn, A, Mattauer, M, Coulon, C, Jaeger, JJ, Achache, J, Schärer, U, Marcoux, J and Burg, JP (1984) Structure and evolution of the Himalaya–Tibet orogenic belt. Nature 307, 1722.CrossRefGoogle Scholar
Beccaluva, L, Ohnenstetter, D and Ohnenstetter, M (1979) Geochemical discrimination between ocean-floor and island-arc tholeiites—application to some ophiolites. Canadian Journal of Earth Sciences 16, 1874–82.CrossRefGoogle Scholar
Blackburn, WH (1969) Zoned and unzoned garnets from the Grenville gneiss around Gananoque, Ontario. Canadian Mineralogist 9, 691–8.Google Scholar
Bloomer, SH, Taylor, B, Macleod, CJ, Stern, RJ, Fryer, P, Hawkins, JW and Johnson, L (1995) Early arc volcanism and the ophiolite problem: a perspective from drilling in the western Pacific. Active Margins and Marginal Basins of the Western Pacific 88, 130.CrossRefGoogle Scholar
Boudier, F, Ceuleneer, G and Nicolas, A (1988) Shear zones, thrusts and related magmatism in the Oman ophiolite: initiation of thrusting on an oceanic ridge. Tectonophysics 151, 275–96.CrossRefGoogle Scholar
Bouilhol, P, Schaltegger, U, Chiaradia, M, Ovtcharova, M, Stracke, A, Burg, JP and Dawood, H (2011) Timing of juvenile arc crust formation and evolution in the Sapat Complex (Kohistan–Pakistan). Chemical Geology 280, 243–56.CrossRefGoogle Scholar
Buckman, S, Aitchison, JC, Nutman, AP, Bennett, VC, Walsh, JMJ, Saktura, WM, Kachovich, S and Langlois, L (2017) The Age, Origin and Collision of the Spongtang Ophiolite, Ladakh Himalaya. In Proceedings of American Geophysical Union Fall Meeting (AGUFM) 2017, 11–15 December 2017, New Orleans, T43E-02.Google Scholar
Burchfiel, BC, Zhiliang, C, Hodges, KV, Yuping, L, Royden, LH and Changrong, D (1992) The South Tibetan detachment system, Himalayan orogen: extension contemporaneous with and parallel to shortening in a collisional mountain belt. Geological Society of America Special Papers 269, doi: 10.1130/SPE269-01.CrossRefGoogle Scholar
Burg, JP, Brunel, M, Gapais, D, Chen, GM and Liu, GH (1984) Deformation of leucogranites of the crystalline Main Central Sheet in southern Tibet (China). Journal of Structural Geology 6, 535–42.CrossRefGoogle Scholar
Caddick, MJ, Konopásek, J and Thompson, AB (2010) Preservation of garnet growth zoning and the duration of prograde metamorphism. Journal of Petrology 51, 2327–47.CrossRefGoogle Scholar
Carlson, WD and Gordon, CL (2004) Effects of matrix grain size on the kinetics of intergranular diffusion. Journal of Metamorphic Geology 22, 733–42.CrossRefGoogle Scholar
Catlos, EJ, Lovera, OM, Kelly, ED, Ashley, KT, Harrison, TM and Etzel, T (2018) Modeling high-resolution pressure-temperature paths across the Himalayan Main Central Thrust (Central Nepal): implications for the dynamics of collision. Tectonics 37, 2363–88.CrossRefGoogle Scholar
Choudhuri, BK, Gururajan, NS and Singh, RKB (2009) Geology and structural evolution of the eastern Himalayan Syntaxis. Himalayan Geology 30, 1734.Google Scholar
Chu, M-F, Chung, S-L, O’Reilly, SY, Pearson, NJ, Wu, F-Y, Li, X-H, Liu, D, Ji, J, Chu, C-H and Lee, H-Y (2011) India’s hidden inputs to Tibetan orogeny revealed by Hf isotopes of Transhimalayan zircons and host rocks. Earth and Planetary Science Letters 307, 479–86.CrossRefGoogle Scholar
Chu, M-F, Chung, S-L, Song, B, Liu, D, O’Reilly, SY, Pearson, NJ, Ji, J and Wen, D-J (2006) Zircon U-Pb and Hf isotope constraints on the Mesozoic tectonics and crustal evolution of southern Tibet. Geology 34, 745–8.CrossRefGoogle Scholar
Church, WT and Stevens, RK (1971) Early Paleozoic ophiolite complexes of the Newfoundland Appalachians as mantle-oceanic crust sequences. Journal of Geophysical Research 76, 1460–66.CrossRefGoogle Scholar
Connolly, JA (2005) Computation of phase equilibria by linear programming: a tool for geodynamic modeling and its application to subduction zone decarbonation. Earth and Planetary Science Letters 236, 524–41.CrossRefGoogle Scholar
Craddock Affinati, S, Hoisch, TD, Wells, ML and Vervoort, JD (2019) Pressure-temperature-time paths from the Funeral Mountains, California, reveal Jurassic retro-arc underthrusting during early Sevier orogenesis. Geological Society of America Bulletin 132(5–6), 1047–65.CrossRefGoogle Scholar
Dale, J, Holland, T and Powell, R (2000) Hornblende–garnet–plagioclase thermobarometry: a natural assemblage calibration of the thermodynamics of hornblende. Contributions to Mineralogy and Petrology 140, 353–62.CrossRefGoogle Scholar
Dewey, JF and Bird, JM (1971) Origin and emplacement of the ophiolite suite: Appalachian ophiolites in Newfoundland. Journal of Geophysical Research 76, 3179–206.CrossRefGoogle Scholar
Etzel, TM, Catlos, EJ, Ataktürk, K, Lovera, OM, Kelly, ED, Çemen, I and Diniz, E (2019) Implications for thrust-related shortening punctuated by extension from P-T paths and geochronology of garnet-bearing schists, Southern (Çine) Menderes Massif, SW Turkey. Tectonics 38, 1974–98.CrossRefGoogle Scholar
Faryad, SW and Kachlík, V (2013) New evidence of blueschist facies rocks and their geotectonic implication for Variscan suture(s) in the Bohemian Massif. Journal of Metamorphic Geology 31, 6382.CrossRefGoogle Scholar
Floyd, PA and Winchester, JA (1975) Magma type and tectonic setting discrimination using immobile elements. Earth and Planetary Science Letters 27, 211–18.CrossRefGoogle Scholar
Gass, IG (1968) Is the Troodos massif of Cyprus a fragment of Mesozoic ocean floor? Nature 220, 3942.CrossRefGoogle Scholar
Ghose, NC and Chatterjee, N (eds) (2014) Ophiolite around the Indian Plate margin. In A Petrographic Atlas of Ophiolite, pp. 924. New Delhi: Springer.CrossRefGoogle Scholar
Ghosh, B, Mahoney, J and Ray, J (2007) Mayodia Ophiolites of Arunachal Pradesh, Northeastern Himalaya. Journal of the Geological Society of India 70, 595604.Google Scholar
Ghosh, B and Ray, J (2003) Mineral chemistry of ophiolitic rocks of Mayodia-Hunli area of Dibang valley district, Arunachal Pradesh, North Eastern India. Memoirs of the Geological Society of India 52, 447–71.Google Scholar
Girardeau, J, Mercier, JC and Yougong, Z (1985a) Origin of the Xigaze ophiolite, Yarlung Zangbo suture zone, southern Tibet. Tectonophysics 119, 407–33.CrossRefGoogle Scholar
Girardeau, J, Mercier, JCC and Yougong, Z (1985b) Structure of the Xigaze ophiolite, Yarlung Zangbo suture zone, southern Tibet, China: genetic implications. Tectonics 4, 267–88.CrossRefGoogle Scholar
Graham, CM and Powell, R (1984) A garnet–hornblende geothermometer: calibration, testing, and application to the Pelona Schist, Southern California. Journal of Metamorphic Geology 2, 1331.CrossRefGoogle Scholar
Green, ECR, White, RW, Diener, JFA, Powell, R, Holland, TJB and Palin, RM (2016) Activity–composition relations for the calculation of partial melting equilibria in metabasic rocks. Journal of Metamorphic Geology 34, 845–69.CrossRefGoogle Scholar
Green, TH (1977) Garnet in silicic liquids and its possible use as a PT indicator. Contributions to Mineralogy and Petrology 65, 5967.CrossRefGoogle Scholar
Guilmette, C, Hébert, R, Wang, C and Villeneuve, M (2009) Geochemistry and geochronology of the metamorphic sole underlying the Xigaze ophiolite, Yarlung Zangbo Suture Zone, south Tibet. Lithos 112, 149–62.CrossRefGoogle Scholar
Gururajan, NS and Choudhuri, BK (2003) Geology and tectonic history of the Lohit Valley, Eastern Arunachal Pradesh, India. Journal of Asian Earth Science 21, 731–41.CrossRefGoogle Scholar
Gururajan, NS and Choudhuri, BK (2007) Geochemistry and tectonic implications of the Trans-Himalayan Lohit plutonic complex, eastern Arunachal Pradesh. Journal of the Geological Society of India 70, 1733.Google Scholar
Haase, KM and Dewey, CW (1996) Geochemistry of lavas from the Ahu and Tupa volcanic fields, Easter Hotspot, southeast Pacific: implications for intraplate magma genesis near a spreading axis. Earth and Planetary Science Letters 137, 129–43.CrossRefGoogle Scholar
Hacker, BR (1994) Rapid emplacement of young oceanic lithosphere: argon geochronology of the Oman ophiolite. Science 265, 1563–5.CrossRefGoogle ScholarPubMed
Hässig, M, Galoyan, G, Bruguier, O, Rolland, Y, Melis, R and Sosson, M (2019) PTT history of the Amasia and Stepanavan sub-ophiolitic metamorphic units (NW Armenia, Lesser Caucasus): implications for metamorphic sole development and for the obduction process. Ofioliti: An International Journal on Ophiolites and Related Topics 44, 4370.Google Scholar
Hébert, R, Bezard, R, Guilmette, C, Dostal, J, Wang, CS and Liu, ZF (2012) The Indus–Yarlung Zangbo ophiolites from Nanga Parbat to Namche Barwa syntaxes, southern Tibet: first synthesis of petrology, geochemistry, and geochronology with incidences on geodynamic reconstructions of Neo-Tethys. Gondwana Research 22, 377–97.CrossRefGoogle Scholar
Holland, T and Blundy, J (1994) Non-ideal interactions in calcic amphiboles and their bearing on amphibole-plagioclase thermometry. Contributions to Mineralogy and Petrology 116, 433–47.CrossRefGoogle Scholar
Holland, TJB and Powell, R (1991) A compensated-Redlich- Kwong (CORK) equation for volumes and fugacities of CO2 and H2O in the range 1 bar to 50 kbar and 100–1600 C. Contributions to Mineralogy and Petrology 109, 265–73.CrossRefGoogle Scholar
Holland, TJB and Powell, R (1998) An internally consistent thermodynamic data set for phases of petrological interest. Journal of Metamorphic Geology 16, 309–43.CrossRefGoogle Scholar
Hsü, KJ, Guitang, P and Sengör, AMC (1995) Tectonic evolution of the Tibetan Plateau: a working hypothesis based on the archipelago model of orogenesis. International Geology Review 37, 473508.CrossRefGoogle Scholar
Irvine, TNJ and Baragar, WRA (1971) A guide to the chemical classification of the common volcanic rocks. Canadian Journal of Earth Sciences 8, 523–48.CrossRefGoogle Scholar
Jamieson, RA (1986) P-T paths from high temperature shear zones beneath ophiolites. Journal of Metamorphic Geology 4, 322.CrossRefGoogle Scholar
Ji, W-Q, Wu, F-Y, Chung, S-L, Li, J-X and Liu, C-Z (2009) Zircon U-Pb geochronology and Hf isotopic constraints on petrogenesis of the Gangdese batholith, southern Tibet. Chemical Geology 262, 229–45.CrossRefGoogle Scholar
Kelly, ED, Hoisch, TD, Wells, ML, Vervoort, JD and Beyene, MA (2015) An Early Cretaceous garnet pressure–temperature path recording synconvergent burial and exhumation from the hinterland of the Sevier orogenic belt, Albion Mountains, Idaho. Contributions to Mineralogy and Petrology 170, 20.CrossRefGoogle Scholar
Kempton, PD and Harmon, RS (1992) Oxygen isotope evidence for large-scale hybridization of the lower crust during magmatic underplating. Geochimica et Cosmochimica Acta 56, 971–86.CrossRefGoogle Scholar
Kepezhinskas, P, McDermott, F, Defant, M, Hochstaedter, A, Drummond, MS, Hawdesworth, CJ, Koloskov, A, Maury, RC and Bellon, H (1997) Trace element and Sr–Nd–Pb isotopic constraints on a three-component model of Kamchatka Arc petrogenesis. Geochimica et Cosmochimica Acta 61, 577600.CrossRefGoogle Scholar
Khogenkumar, S, Singh, AK, Singh, RB, Khanna, PP, Singh, NI and Singh, WI (2016) Coexistence of MORB and OIB-type mafic volcanics in the Manipur Ophiolite Complex, Indo-Myanmar Orogenic Belt, northeast India: implication for heterogeneous mantle source at the spreading zone. Journal of Asian Earth Sciences 116, 4258.CrossRefGoogle Scholar
Kohn, MJ and Spear, FS (1990) Two new geobarometers for garnet amphibolites, with applications to southeastern Vermont. American Mineralogist 75, 8996.Google Scholar
Kretz, R (1983) Symbols for rock-forming minerals. American Mineralogist 68, 277–9.Google Scholar
Leake, BE (1978) Nomenclature of amphiboles. American Mineralogist 63, 1023–52.Google Scholar
Le Bas, MJ, Le Maitre, RW and Woolley, AR (1992) The construction of the total alkali-silica chemical classification of volcanic rocks. Mineralogy and Petrology 46, 122.CrossRefGoogle Scholar
Le Maitre, RW (1984) A proposal by the IUGS Subcommission on the Systematics of Igneous Rocks for a chemical classification of volcanic rocks based on the total alkali silica (TAS) diagram (on behalf of the IUGS Subcommission on the Systematics of Igneous Rocks). Australian Journal of Earth Sciences 31, 243–55.CrossRefGoogle Scholar
Le Roex, AP, Dick, HJB, Erlank, AJ, Reid, AM, Frey, FA and Hart, SR (1983) Geochemistry, mineralogy and petrogenesis of lavas erupted along the Southwest Indian Ridge between the Bouvet triple junction and 11 degrees east. Journal of Petrology 24, 267318.CrossRefGoogle Scholar
Lin, TH, Chung, SL, Kumar, A, Wu, FY, Chiu, HY and Lin, IJ (2013) Linking a prolonged Neo-Tethyan magmatic arc in South Asia: zircon U-Pb and Hf isotopic constraints from the Lohit Batholith, NE India. Terra Nova 25, 453–8.CrossRefGoogle Scholar
Liu, SW, Shen, QH and Geng, YS (1996) Metamorphic evolution of two types of garnet-granulites in northwestern Hebei Province and analyses by Gibbs method. Acta Petrology Sinica 12, 261–75 (in Chinese with English abstract).Google Scholar
Lou, Y, Wei, C, Liu, X, Zhang, C, Tian, Z and Wang, W (2013) Metamorphic evolution of garnet amphibolite in the western Dabieshan eclogite belt, Central China: evidence from petrography and phase equilibria modeling. Journal of Asian Earth Sciences 63, 130–38.CrossRefGoogle Scholar
Lucas-Tooth, HJ and Pyne, C (1964) The accurate determination of major constituents by X-ray fluorescence analysis in the presence of large interelement effects. Advances in X-ray Analysis 7, 523–41.CrossRefGoogle Scholar
Mahoney, JJ, Sheth, HC, Chandrasekharam, D and Peng, ZX (2000) Geochemistry of flood basalts of the Toranmal section, northern Deccan Traps, India: implications for regional Deccan stratigraphy. Journal of Petrology 41, 1099–120.CrossRefGoogle Scholar
Malpas, J (1979) The dynamothermal aureole of the Bay of Islands ophiolite suite. Canadian Journal of Earth Sciences 16, 2086–101.CrossRefGoogle Scholar
Misra, DK (2009) Litho-tectonic sequence and their regional correlation along the Lohit and Dibang valleys, eastern Arunachal Pradesh. Journal of the Geological Society of India 73, 213–19.CrossRefGoogle Scholar
Mitchell, AHJ (1981) Phenerozoic plate boundaried in mainland SE Asia, the Himalaya and Tibet. Journal of the Geological Society, London 138, 109–22.CrossRefGoogle Scholar
Miyashiro, A (1994) Metamorphic Petrology. Boca Raton: CRC Press.Google Scholar
Moores, E (1970) Ultramafics and orogeny, with models of the US Cordillera and the Tethys. Nature 228, 837–42.CrossRefGoogle ScholarPubMed
Moores, EM and Vine, FJ (1971) The Troodos Massif, Cyprus and other ophiolites as oceanic crust: evaluation and implications. Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences 268, 443–67.Google Scholar
Moynihan, DP and Pattison, DRM (2013a) An automated method for the calculation of P–T paths from garnet zoning, with application to metapelitic schist from the Kootenay Arc, British Columbia, Canada. Journal of Metamorphic Geology 31, 525–48.CrossRefGoogle Scholar
Moynihan, DP and Pattison, DRM (2013b) Barrovian metamorphism in the central Kootenay Arc, British Columbia: petrology and isograd geometry. Canadian Journal of Earth Sciences 50, 769–4.CrossRefGoogle Scholar
Müller, G and Schneider, A (1971) Chemistry and genesis of garnets in metamorphic rocks. Contributions to Mineralogy and Petrology 31, 178200.CrossRefGoogle Scholar
Muncill, GE and Chamberlain, CP (1988) Crustal cooling rates inferred from homogenization of metamorphic garnets. Earth and Planetary Science Letters 87, 390–6.CrossRefGoogle Scholar
Nandy, DR (1973) Geology and structural lineaments of the Lohit Himalaya (Arunachal Pradesh) and adjoining area. In Seminar on Geodynamics of the Himalayan Region (ed. Gupta, HK), pp. 167–72. Hyderabad: National Geophysical Research Institute.Google Scholar
Newton, RC, Charlu, TV and Kleppa, OJ (1980) Thermochemistry of the high structural Arai state plagioclases. Geochimica et Cosmochimica Acta 44, 933–41.CrossRefGoogle Scholar
Nicolas, A, Girardeau, J, Marcoux, J, Dupre, B, Xibin, W, Yougong, C, Haixiang, Z and Xuchang, X (1981) The Xigaze ophiolite (Tibet): a peculiar oceanic lithosphere. Nature 294, 414–17.CrossRefGoogle Scholar
Nicolas, A and Le Pichon, X (1980) Thrusting of young lithosphere in subduction zones with special reference to structures in ophiolitic peridotites. Earth and Planetary Science Letters 46, 397406.CrossRefGoogle Scholar
Niu, Y (2004) Bulk-rock major and trace element compositions of abyssal peridotites: implications for mantle melting, melt extraction and post-melting processes beneath mid-ocean ridges. Journal of Petrology 45, 2423–58.CrossRefGoogle Scholar
Niu, Y, Regelous, M, Wendt, IJ, Batiza, R and O’Hara, MJ (2002) Geochemistry of near-EPR seamounts: importance of source vs. process and the origin of enriched mantle component. Earth and Planetary Science Letters 199, 327–45.CrossRefGoogle Scholar
Pearce, JA (1982) Trace element characteristics of lavas from destructive plate boundaries. Andesites 8, 525–48.Google Scholar
Pearce, JA and Cann, JR (1973) Tectonic setting of basic volcanic rocks determined using trace element analyses. Earth and Planetary Science Letters 19, 290300.CrossRefGoogle Scholar
Pearce, JA and Norry, MJ (1979) Petrogenetic implications of Ti, Zr, Y, and Nb variations in volcanic rocks. Contributions to Mineralogy and Petrology 69, 3347.CrossRefGoogle Scholar
Pearce, JA and Peate, DW (1995) Tectonic implications of the composition of volcanic arc magmas. Annual Review of Earth & Planetary Sciences 23, 251–85.CrossRefGoogle Scholar
Pearce, JA and Stern, RJ (2006) Origin of back-arc basin magmas: trace element and isotope perspectives. Geophysical Monograph-American Geophysical Union 166, 63.Google Scholar
Photiades, A, Saccani, E and Tassinari, R (2003) Petrogenesis and tectonic setting of volcanic rocks from the Subpelagonian ophiolitic mélange in the Agoriani area (Othrys, Greece). Ofioliti 28, 121–35.Google Scholar
Powell, R and Holland, TJB (1988) An internally consistent dataset with uncertainties and correlations: 3. Applications to geobarometry, worked examples and a computer program. Journal of Metamorphic Geology 6, 173204.CrossRefGoogle Scholar
Powell, R and Holland, T (1994) Optimal geothermometry and geobarometry. American Mineralogist 79, 120–33.Google Scholar
Qian, JH and Wei, CJ (2016) P–T–t evolution of garnet amphibolites in the Wutai–Hengshan area, North China Craton: insights from phase equilibria and geochronology. Journal of Metamorphic Geology 34, 423–46.CrossRefGoogle Scholar
Quanru, G, Guitang, P, Zheng, L, Chen, Z, Fisher, RD, Sun, Z, Ou, C, Dong, H, Wang, X, Li, S and Lou, X (2006) The Eastern Himalayan syntaxis: major tectonic domains, ophiolitic mélanges and geologic evolution. Journal of Asian Earth Sciences 27, 265–85.CrossRefGoogle Scholar
Ravikant, V, Wu, F-Y and Ji, W-Q (2009) Zircon U–Pb and Hf isotopic constraints on petrogenesis of the Cretaceous–Tertiary granites in eastern Karakoram and Ladakh, India. Lithos 110, 153166.CrossRefGoogle Scholar
Ravna, EK (2000) Distribution of Fe2+ and Mg between coexisting garnet and hornblende in synthetic and natural systems: an empirical calibration of the garnet–hornblende Fe–Mg geothermometer. Lithos 53, 265–77.CrossRefGoogle Scholar
Saccani, E (2015) A new method of discriminating different types of post-Archean ophiolitic basalts and their tectonic significance using Th-Nb and Ce-Dy-Yb systematics. Geoscience Frontiers 6, 481501.CrossRefGoogle Scholar
Sánchez-Vizcaıno, VL, Gómez-Pugnaire, JM, Azor, MT and Fernández-Soler, A (2003) Phase diagram sections applied to amphibolites: a case study from the Ossa–Morena/Central Iberian Variscan suture (Southwestern Iberian Massif). Lithos 68, 121.CrossRefGoogle Scholar
Sawyer, EW (2001) Melt segregation in the continental crust: distribution and movement of melt in anatectic rocks. Journal of Metamorphic Geology 19(3), 291309.CrossRefGoogle Scholar
Sengör, AC and Natal’in, BA (1996) Turkic-type orogeny and its role in the making of the continental crust. Annual Review of Earth and Planetary Sciences 24, 263337.CrossRefGoogle Scholar
Sharma, KK, Choubey, VM and Chatti, HR (1991) Geological setting of the ophiolites and magmatic arc of the Lohit Himalaya (Arunachal Pradesh), India with special reference to their petrochemistry. Physics and Chemistry of the Earth 18, 277–92.CrossRefGoogle Scholar
Shervais, JW (1982) Ti-V plots and the petrogenesis of modern and ophiolitic lavas. Earth and Planetary Science Letters 59, 101–18.CrossRefGoogle Scholar
Singh, S and Chowdhary, PK (1990) An outline of the geological framework of the Arunachal Himalaya. Himalayan Geology 1, 189–97.Google Scholar
Singh, S and Malhotra, G (1983) Tectonic Set-up of Yang Sang Chu Valley, West Siang, Arunachal Pradesh. New Delhi: Himalayan Shears Hindustan Books, pp. 107–13.Google Scholar
Singh, AK and Singh, RKB (2011) Zn-and Mn-rich chrome-spinels in serpentinite of Tidding Suture Zone, Eastern Himalaya and their metamorphism and genetic significance. Current Science 100, 743–9.Google Scholar
Singh, AK and Singh, RKB (2013) Genetic implications of Zn- and Mn-rich Cr-spinels in serpentinites of the Tidding Suture Zone, eastern Himalaya, NE India. Geological Journal 48, 2238.CrossRefGoogle Scholar
Slater, L, McKenzie, DAN, Grönvold, K and Shimizu, N (2001) Melt generation and movement beneath Theistareykir, NE Iceland. Journal of Petrology 42, 321–54.CrossRefGoogle Scholar
Sorensen, SS and Barton, MD (1987) Metasomatism and partial melting in a subduction complex Catalina Schist, southern California. Geology 15, 115–18.2.0.CO;2>CrossRefGoogle Scholar
Spear, FS (1991) On the interpretation of peak metamorphic temperatures in light of garnet diffusion during cooling. Journal of Metamorphic Geology 9, 379–88.CrossRefGoogle Scholar
Spray, JG (1984) Possible causes and consequences of upper mantle decoupling and ophiolite displacement. In Ophiolites and Oceanic Lithosphere (eds Gass, IG, Lippard, SJ and Shelton, AW), pp. 255–68. Geological Society of London, Special Publication no. 13.Google Scholar
Sturt, BA (1962) The composition of garnets from pelitic schists in relation to the grade of regional metamorphism. Journal of Petrology 3, 181–91.CrossRefGoogle Scholar
Sun, SS and McDonough, WFS (1989) Chemical and isotopic-systematics of oceanic basalts: implications for mantle composition and processes. In Magmatism in Ocean Basins (eds Saunders, AD and Norry, MJ), pp. 313–45. Geological Society of London, Special Publication no. 42.Google Scholar
Surour, AA (1995) Medium-to high-pressure garnet-amphibolites from Gebel Zabara and Wadi Sikait, south Eastern Desert, Egypt. Journal of African Earth Sciences 21, 443–57.CrossRefGoogle Scholar
Temple, PG and Zimmerman, J (1969) Tectonic significance of Alpine ophiolites in Greece and Turkey. Geological Society of America, Abstracts with Programs 7, 222.Google Scholar
Thakur, VC (1998) Structure of the Chamba nappe and position of the Main Central Thrust in Kashmir Himalaya. Journal of Asian Earth Sciences 16, 269–82.CrossRefGoogle Scholar
Thakur, VC and Jain, AK (1975) Some observations of deformation and metamorphism in the rocks of some parts of Mishmi Hills, Lohit district, (NEFA), Arunachal Pradesh. Himalayan Geology 5, 339–64.Google Scholar
Thakur, VC and Rawat, BS (1992) Geological Map of the Western Himalaya. Dehradun, Uttarakhand, India: Printing Group of Survey of India, p. 101.Google Scholar
Wakabayashi, J and Dilek, Y (2000) Spatial and temporal relationships between ophiolites and their metamorphic soles: a test of models of forearc ophiolite genesis. Geological Society of America, Special Papers 349, 5364.Google Scholar
Wakabayashi, J and Dilek, Y (2003) What constitutes ‘emplacement’ of an ophiolite?: mechanisms and relationship to subduction initiation and formation of metamorphic soles. In Ophiolites in Earth History (eds Dilek, Y and Robinson, PT), pp. 427–47. Geological Society of London, Special Publication no. 218.Google Scholar
Wang, WL, Aitchison, JC, Lo, CH and Zeng, QG (2008) Geochemistry and geochronology of the amphibolite blocks in ophiolitic mélanges along Bangong-Nujiang suture, central Tibet. Journal of Asian Earth Sciences 33, 122–38.CrossRefGoogle Scholar
Wei, CJ (2011) Approaches and advancement of the study of metamorphic P-T-t paths. Earth Science Frontiers 18, 116.Google Scholar
Whitechurch, H, Juteau, T and Montigny, R (1984) Role of the Eastern Mediterranean ophiolites (Turkey, Syria, Cyprus) in the history of the Neo-Tethys. In The Geological Evolution of the Eastern Mediterranean (eds Dixon, JE and Robertson, AHF), pp. 301–17. Geological Society of London, Special Publication no. 17.Google Scholar
Williams, H and Smyth, WR (1973) Metamorphic aureoles beneath ophiolite suites and Alpine peridotites: tectonic implications with west Newfoundland examples. American Journal of Science 273, 594621.CrossRefGoogle Scholar
Winchester, JA and Floyd, PA (1976) Geochemical magma type discrimination: application to altered and metamorphosed basic igneous rocks. Earth and Planetary Science Letters 28, 459–69.CrossRefGoogle Scholar
Winchester, JA and Floyd, PA (1977) Geochemical discrimination of different magma series and their differentiation products using immobile elements. Chemical Geology 20, 325–43.CrossRefGoogle Scholar
Wood, DA, Joron, JL and Treuil, M (1979) A re-appraisal of the use of trace elements to classify and discriminate between magma series erupted in different tectonic settings. Earth and Planetary Science Letters 45, 326–36.CrossRefGoogle Scholar
Woodsworth, GJ (1977) Homogenization of zoned garnets from pelitic schists. Canadian Mineralogist 15, 230–42.Google Scholar
Wu, KK, Zhao, G, Sun, M, Yin, C, He, Y and Tam, PY (2013) Metamorphism of the northern Liaoning Complex: implications for the tectonic evolution of Neoarchean basement of the Eastern Block, North China Craton. Geoscience Frontiers 4, 305–20.CrossRefGoogle Scholar
Xu, ZQ, Dilek, Y, Yang, JS, Liang, FH, Liu, F, Ba, DZ, Cai, ZH, Li, GW, Dong, HW and Ji, SC (2015) Crustal structure of the Indus–Tsangpo suture zone and its ophiolites in southern Tibet. Gondwana Research 27, 507–24.CrossRefGoogle Scholar
Yardley, BWD (1977) An empirical study of diffusion in garnet. American Mineralogist 62, 793800.Google Scholar
Yin, A and Harrison, TM (2000) Geologic evolution of the Himalayan-Tibetan orogen. Annual Review of Earth and Planetary Sciences 28, 211–80.CrossRefGoogle Scholar
Zhang, Y, Li, XP, Sun, G, Wang, Z and Duan, W (2019) Metamorphic petrology of clinopyroxene amphibolite from the Xigaze Ophiolite, Southern Tibet: PT constraints and phase equilibrium modeling. Journal of Earth Science 30, 549–62.CrossRefGoogle Scholar
Zhao, G, Cawood, P and Lu, L (1999) Petrology and P–T history of the Wutai amphibolites: implications for tectonic evolution of the Wutai Complex, China. Precambrian Research 93, 181–99.CrossRefGoogle Scholar
Zhao, JH and Zhou, MF (2007) Geochemistry of Neoproterozoic mafic intrusions in the Panzhihua district (Sichuan Province, SW China): implications for subduction-related metasomatism in the upper mantle. Precambrian Research 152, 2747.CrossRefGoogle Scholar
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