The structural geometry, metamorphic and magmatic evolution of the Everest massif, High Himalaya of Nepal-South Tibet

doi:10.1144/0016-764902-126

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Journal of the Geological Society; 2003; v. 160; issue.3; p. 345-366;
DOI: 10.1144/0016-764902-126
© 2003 Geological Society of London

Original Article

The structural geometry, metamorphic and magmatic evolution of the Everest massif, High Himalaya of Nepal–South Tibet

M.P. SEARLE¹, R.L. SIMPSON¹, R.D. LAW², R.R. PARRISH³ & D.J. WATERS¹

¹ ¹Department of Earth Sciences, Oxford University, Parks Road, Oxford OX1 3PR, UK (e-mail: mike.searle@earth.ox.ac. uk)
² ²Department of Geological Sciences, Virginia Tech., Blacksburg, Virginia 24061, USA
³ ³Department of Geology, Leicester University, Leicester LE1 7RH, and NERC Isotope Geosciences Laboratory, Keyworth, Nottingham, NG12 5GG

This paper presents a new geological map together with cross-sectionsand lateral sections of the Everest massif. We combine fieldrelations, structural geology, petrology, thermobarometry andgeochronology to interpret the tectonic evolution of the EverestHimalaya. Lithospheric convergence of India and Asia since collisionat c. 50 Ma. resulted in horizontal shortening, crustal thickeningand regional metamorphism in the Himalaya and beneath southernTibet. High temperatures (>620 °C) during sillimanitegrade metamorphism were maintained for 15 million years from32 to 16.9 ± 0.5 Ma along the top of the Greater Himalayanslab. This implies that crustal thickening must also have beenactive during this time, which in turn suggests high topographyduring the Oligocene–early Miocene. Two low-angle normalfaults cut the Everest massif at the top of the Greater Himalayanslab. The earlier, lower Lhotse detachment bounds the upperlimit of massive leucogranite sills and sillimanite–cordieritegneisses, and has been locally folded. Ductile motion alongthe top of the Greater Himalayan slab was active from 18 to16.9 Ma. The upper Qomolangma detachment is exposed in the summitpyramid of Everest and dips north at angles of less than 15°.Brittle faulting along the Qomolangma detachment, which cutsall leucogranites in the footwall, was post-16 Ma. Footwallsillimanite gneisses and leucogranites are exposed along theKharta valley up to 57 km north of the Qomolangma detachmentexposure near the summit of Everest. The amount of extrusionof footwall gneisses and leucogranites must have been around200 km southwards, from an origin at shallow levels (12–18km depth) beneath Tibet, supporting models of ductile extrusionof the Greater Himalayan slab. The Everest–Lhotse–Nuptsemassif contains a massive ballooning sill of garnet + muscovite+ tourmaline leucogranite up to 3000 m thick, which reaches7800 m on the Kangshung face of Everest and on the south faceof Nuptse, and is mainly responsible for the extreme altitudeof both mountains. The middle crust beneath southern Tibet isinferred to be a weak, ductile-deforming zone of high heat andlow friction separating a brittle deforming upper crust abovefrom a strong (?granulite facies) lower crust with a rheologicallystrong upper mantle. Field evidence, thermobarometry and U–Pbgeochronological data from the Everest Himalaya support thegeneral shear extrusive flow of a mid-crustal channel from beneaththe Tibetan plateau. The ending of high temperature metamorphismin the Himalaya and of ductile shearing along both the MainCentral Thrust and the South Tibetan Detachment normal faultsroughly coincides with initiation of strike-slip faulting andeast–west extension in south Tibet (<18 Ma).

Key Words: Everest • Himalaya • geological map • leucogranite • extension • compression

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