Himalayan inverted metamorphism and syn-convergence extension as a consequence of a general shear extrusion

JEAN-CLAUDE VANNAY; BERNHARD GRASEMANN

doi:10.1017/S0016756801005313

Abstract

Two paradoxical geological features of the Himalaya are the syn-convergence extension and the inverted metamorphic isograds observed in the crystalline core zone of this orogen. This High Himalayan Crystalline Sequence corresponds to an up to 40 km thick sequence of amphibolite to granulite facies gneiss, bounded by the Main Central Thrust at the base, and by the extensional faults of the South Tibetan Detachment System at the top. Geochronological and structural data demonstrate that coeval movements along both the Main Central Thrust and South Tibetan Detachment System during Early to Middle Miocene times were related to a tectonically controlled exhumation of these high-grade metamorphic rocks. The High Himalayan Crystalline Sequence systematically shows an inverted metamorphic zonation, generally characterized by a gradual superposition of garnet, staurolite, kyanite, sillimanite + muscovite and sillimanite + K-feldspar isograds, from the base to the top of the unit. Recent kinematic flow analyses of these metamorphic rocks demonstrate the coexistence of both simple shear and pure shear during the ductile deformation. The simple shear component of such a general non-coaxial flow could explain a rotation of isograds, eventually resulting in an inversion. The pure shear component of the flow implies a thinning of the metamorphic sequence that must be balanced by a perpendicular stretching of the unit parallel to its boundaries. Inasmuch as seismic data show that both the Main Central Thrust and South Tibetan Detachment System converge at depth, a thinning of the wedge-shaped High Himalayan Crystalline Sequence should induce a ductile extrusion of these high-grade rocks toward the surface. Rapid extension at the top of the sequence could thus be the consequence of a general shear extrusion of this unit relative to its hanging wall. Moreover, this extensional movement should decrease with depth to become zero where the boundaries of the unit meet, accounting for the paradoxical convergence of the South Tibetan Detachment System toward the Main Central Thrust. Furthermore, a general flow combining simple shear and pure shear can reconcile inverted isograds with the lack of inverted pressure field gradient across the High Himalayan Crystalline Sequence, despite an intense non-coaxial deformation. In good agreement with the seismic, kinematic and P–T–t constraints on the Himalayan tectono-thermal evolution, general shear extrusion provides a consistent model accounting for both inverted isograds and rapid extension in a compressional orogenic setting.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Beaumont, C. Jamieson, R. A. Nguyen, M. H. and Lee, B. 2001. Himalayan tectonics explained by extrusion of a low-viscosity crustal channel coupled to focused surface denudation. Nature, Vol. 414, Issue. 6865, p. 738.

Wiesmayr, Gerhard and Grasemann, Bernhard 2002. Eohimalayan fold and thrust belt: Implications for the geodynamic evolution of the NW‐Himalaya (India). Tectonics, Vol. 21, Issue. 6,

Whittington, A. G. and Treloar, P. J. 2002. Crustal anatexis and its relation to the exhumation of collisional orogenic belts, with particular reference to the Himalaya. Mineralogical Magazine, Vol. 66, Issue. 1, p. 53.

Wiesmayr, G. Edwards, M. A. Meyer, M. Kidd, W. S. F. Leber, D. Häusler, H. and Wangda, D. 2002. Evidence for steady fault-accommodated strain in the High Himalaya: progressive fault rotation of the southern Tibet detachment system in NW Bhutan. Geological Society, London, Special Publications, Vol. 200, Issue. 1, p. 371.

Carosi, Rodolfo Montomoli, Chiara and Visonà, Dario 2002. Is there any detachment in the Lower Dolpo (western Nepal)? . Comptes Rendus. Géoscience, Vol. 334, Issue. 12, p. 933.

Robyr, M Vannay, J.-C Epard, J.-L and Steck, A 2002. Thrusting, extension, and doming during the polyphase tectonometamorphic evolution of the High Himalayan Crystalline Zone in NW India. Journal of Asian Earth Sciences, Vol. 21, Issue. 3, p. 221.

SEARLE, M.P. SIMPSON, R.L. LAW, R.D. PARRISH, R.R. and WATERS, D.J. 2003. The structural geometry, metamorphic and magmatic evolution of the Everest massif, High Himalaya of Nepal–South Tibet. Journal of the Geological Society, Vol. 160, Issue. 3, p. 345.

Searle, Michael P. and Godin, Laurent 2003. The South Tibetan Detachment and the Manaslu Leucogranite: A Structural Reinterpretation and Restoration of the Annapurna‐Manaslu Himalaya, Nepal. The Journal of Geology, Vol. 111, Issue. 5, p. 505.

Daniel, C. G. Hollister, L. S. Parrish, R. R. and Grujic, D. 2003. Exhumation of the Main Central Thrust from Lower Crustal Depths, Eastern Bhutan Himalaya. Journal of Metamorphic Geology, Vol. 21, Issue. 4, p. 317.

Xypolias, P Kokkalas, S and Skourlis, K 2003. Upward extrusion and subsequent transpression as a possible mechanism for the exhumation of HP/LT rocks in Evia Island (Aegean Sea, Greece). Journal of Geodynamics, Vol. 35, Issue. 3, p. 303.

Robinson, D.M. DeCelles, P.G. Garzione, C.N. Pearson, O.N. Harrison, T.M. and Catlos, E.J. 2003. Kinematic model for the Main Central thrust in Nepal. Geology, Vol. 31, Issue. 4, p. 359.

Beaumont, Christopher Jamieson, Rebecca A. Nguyen, Mai H. and Medvedev, Sergei 2004. Crustal channel flows: 1. Numerical models with applications to the tectonics of the Himalayan‐Tibetan orogen. Journal of Geophysical Research: Solid Earth, Vol. 109, Issue. B6,

Bhadra, S Gupta, S and Banerjee, M 2004. Structural evolution across the Eastern Ghats Mobile Belt–Bastar craton boundary, India: hot over cold thrusting in an ancient collision zone. Journal of Structural Geology, Vol. 26, Issue. 2, p. 233.

Thiede, Rasmus C. Bookhagen, Bodo Arrowsmith, J.Ramón Sobel, Edward R. and Strecker, Manfred R. 2004. Climatic control on rapid exhumation along the Southern Himalayan Front. Earth and Planetary Science Letters, Vol. 222, Issue. 3-4, p. 791.

DiPietro, Joseph A. and Pogue, Kevin R. 2004. Tectonostratigraphic subdivisions of the Himalaya: A view from the west. Tectonics, Vol. 23, Issue. 5,

Brueckner, Hannes K. and van Roermund, Herman L. M. 2004. Dunk tectonics: A multiple subduction/eduction model for the evolution of the Scandinavian Caledonides. Tectonics, Vol. 23, Issue. 2,

Kokkalas, S. and Doutsos, T. 2004. Kinematics and strain partitioning in the southeast Hellenides (Greece). Geological Journal, Vol. 39, Issue. 2, p. 121.

Law, R.D. Searle, M.P. and Simpson, R.L. 2004. Strain, deformation temperatures and vorticity of flow at the top of the Greater Himalayan Slab, Everest Massif, Tibet. Journal of the Geological Society, Vol. 161, Issue. 2, p. 305.

Dasgupta, S. Ganguly, J. and Neogi, S. 2004. Inverted metamorphic sequence in the Sikkim Himalayas: crystallization history, P–T gradient and implications. Journal of Metamorphic Geology, Vol. 22, Issue. 5, p. 395.

Indares, Aphrodite and Dunning, Greg 2004. Crustal architecture above the high-pressure belt of the Grenville Province in the Manicouagan area: new structural, petrologic and U–Pb age constraints. Precambrian Research, Vol. 130, Issue. 1-4, p. 199.

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Himalayan inverted metamorphism and syn-convergence extension as a consequence of a general shear extrusion

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