U(Th)Pb systematics and ages of Himalayan leucogranites, South Tibet

Abstract The age and origin of five leucogranites from the High and Tethys Himalaya, and two country-rock gneisses were investigated by U Pb dating of zircon fractions and single grains, and fractions of monazite. Additionally, Th U concentrations in whole rock powders and isotopic compositions of Pb in leached K-feldspars were determined. Monazites yield ages of 16.8 ± 0.6 m.y. for the Nialam migmatite-granite, 15.1 ± 0.5 m.y. for the Lhagoi Kangri granite, 14.3 ± 0.6 m.y. for a granite from Mt. Everest, and 9.8 ± 0.7 m.y. and 9.2 ± 0.9 m.y. for two varieties of the Maja granite. These data, together with monazite ages of 21.9 ± 0.2 and 24.0 ± 0.4 m.y., determined earlier on the Makalu granite [1], substantiate a period of intracontinental granite emplacements from 24 to 9 m.y. ago, i.e. from uppermost Oligocene to late Miocene times. Such a period of plutonic activity is consistent with the view that all these granites result from intracrustal melting following the collision of India with Eurasia. Furthermore, the individual ages, together with structural relationships between granites and country rocks suggest that granite formation and tectono-metamorphism occurred as alternating and strongly related processes with a periodicity of 7 to 9 m.y. Inherited lead components, present in all granite zircons point to large proportions of Precambrian material in the magma source regions, up to 2200 m.y. old. Th U systematics between monazite and country rocks indicate that U has been leached from most of the granites after crystallisation of monazite. Zircon dating of the Kangmar granite gneiss, which occurs in a window through the Tethys Himalayan sediments, shows that this pluton, transformed to a gneiss during the Alpine orogeny, crystallised in lowermost Palaeozoic times 562 ± 4 m.y. ago.

[1]  B. Journet,et al.  Deep structure of southern Tibet inferred from the dispersion of Rayleigh waves through a long-period seismic network , 1985, Nature.

[2]  Wang Xibin,et al.  Structure and evolution of the Himalaya–Tibet orogenic belt , 1984, Nature.

[3]  U. Schärer The effect of initial230Th disequilibrium on young UPb ages: the Makalu case, Himalaya , 1984 .

[4]  P. Bird Initiation of intracontinental subduction in the Himalaya , 1978 .

[5]  Ronghua Xu,et al.  The Pb-isotope geochemistry of granitoids from the Himalaya-Tibet collision zone: implications for crustal evolution , 1985 .

[6]  U. Schärer,et al.  Magmatism and Metamorphism in the Lhasa Block (Tibet): A Geochronological Study , 1985, The Journal of Geology.

[7]  J. Burg,et al.  Himalayan metamorphism and deformations in the North Himalayan Belt (southern Tibet, China) , 1984 .

[8]  A. Gansser,et al.  Contrasting18O enrichment and origins of High Himalayan and Transhimalayan intrusives , 1983 .

[9]  C. Jaupart,et al.  High heat flow in southern Tibet , 1984, Nature.

[10]  P. Zeitler,et al.  Unroofing history of a suture zone in the Himalaya of Pakistan by means of fission-track annealing ages , 1982 .

[11]  P. Fort Manaslu leucogranite: A collision signature of the Himalaya: A model for its genesis and emplacement , 1981 .

[12]  P. Molnar,et al.  Cenozoic Tectonics of Asia: Effects of a Continental Collision: Features of recent continental tectonics in Asia can be interpreted as results of the India-Eurasia collision. , 1975, Science.

[13]  A. Nercessian,et al.  Lhasa block and bordering sutures— a continuation of a 500-km Moho traverse through Tibet , 1984, Nature.

[14]  U. Schärer,et al.  The Palung granite (Himalaya); high-resolution UPb systematics in zircon and monazite , 1983 .

[15]  G. Ferrara,et al.  Rb/Sr geochronology of granites and gneisses from the Mount Everest region, Nepal Himalaya , 1983 .

[16]  M. H. Dodson Kinetic processes and thermal history of slowly cooling solids , 1976, Nature.

[17]  D. Othman,et al.  Nd–Sr isotopic relationship in granitoid rocks and continental crust development: a chemical approach to orogenesis , 1980, Nature.

[18]  F. Albarède,et al.  238U/206Pb-235U/207Pb-232Th/208Pb zircon geochronology in alpine and non-alpine environment , 1974 .

[19]  U. Schärer,et al.  The Transhimalaya (Gangdese) plutonism in the Ladakh region: a UPb and RbSr study , 1984 .

[20]  Timothy P. Loomis,et al.  Tertiary mantle diapirism, orogeny, and plate tectonics east of the Strait of Gibraltar , 1975 .

[21]  T. Krogh A low-contamination method for hydrothermal decomposition of zircon and extraction of U and Pb for isotopic age determinations , 1973 .

[22]  P. Molnar,et al.  Calculated temperatures in overthrust terrains and possible combinations of heat sources responsible for the Tertiary granites in the greater Himalaya , 1983 .

[23]  M. Condomines,et al.  Fine chronology of volcanic processes using 238U-230Th systematics , 1976 .

[24]  U. Schärer,et al.  UPb geochronology of Gangdese (Transhimalaya) plutonism in the Lhasa-Xigaze region, Tibet , 1984 .

[25]  A. Cocherie,et al.  Geochemical investigations of the origin of the Manaslu leucogranite (Himalaya, Nepal) , 1982 .

[26]  J. Achache,et al.  India–Eurasia collision chronology has implications for crustal shortening and driving mechanism of plates , 1984, Nature.

[27]  A. Provost,et al.  Heat focussing, granite genesis and inverted metamorphic gradients in continental collision zones , 1985 .

[28]  R. Armijo,et al.  The Tibetan side of the India–Eurasia collision , 1981, Nature.

[29]  C. Jaupart,et al.  On the thermal structure of the southern Tibetan crust , 1985 .

[30]  N. C. Ghose,et al.  Experimental study of granitic rocks of Darjeeling (West Bengal, India) and its application to the origin of himalayan granites , 1977 .

[31]  G. Manhès,et al.  Comparative uranium-thorium-lead and rubidium-strontium study of the Saint Sèverin amphoterite: consequences for early solar system chronology , 1978 .

[32]  P. Conaghan,et al.  Plate tectonics and the Himalayas , 1973 .

[33]  B. Doe,et al.  U-Th-Pb systematics in hydrothermally altered granites from the Granite Mountains, Wyoming , 1981 .