Development of extensional stresses in the compressional setting of the Himalayan thrust wedge: inference from numerical modelling

Ganesh Raj Joshi; Daigoro Hayashi

doi:10.4236/ns.2010.27083

Natural Science > Vol.2 No.7, July 2010

Development of extensional stresses in the compressional setting of the Himalayan thrust wedge: inference from numerical modelling

Ganesh Raj Joshi, Daigoro Hayashi
.
DOI: 10.4236/ns.2010.27083 PDF HTML 7,837 Downloads 14,287 Views Citations

Abstract

The estimation of contemporary tectonic stress field and deformation in active fold-and-thrust belts are imperative in identifying active geodynamics and resulting faulting phenomenon. In this paper, we focus on contemporary extensional tectonics in the overall compressive setting of the Himalayan orogen. Here we examine the regional tectonic stress field and upper crustal deformation in the Himalayan thrust wedge using a 2D finite element technique, incorporating elastic rheology under plain strain condition. The elastic models demonstrate that the extensional tectonic stress and related nor- mal faulting is extensively developed in the southern front of the Himalaya at shallow crustal level (< 10 km in depth). Our modelling shows a good consistency with the geological field evidences of active faulting, focal mechanism solutions of medium size earthquakes in the several sectors of the Himalaya. Results based on numerical simulation, tectonic analysis and taking geological and geophysical data into account, we interpret that the present-day extensional tectonic activity is not restricted in the southern Tibet but distributed in the different sectors of the Himalayan fold-and-thrust belt co-exist with compressional structures. Modelling results also indicate that the nature, distribution and orientation of the maximum compressive stress (?1) of the Himalaya are mainly controlled by the intra crustal Main Himalayan décollement (MHT). The significant amount of shear stress/strain concentration along the MHT in the western Nepal predict that the region is prone to moderate and great future earthquakes.

Keywords

Extensional Stress Field; Convergent Displacement; Finite Element Modelling; Himalayan Wedge

Share and Cite:

Joshi, G. and Hayashi, D. (2010) Development of extensional stresses in the compressional setting of the Himalayan thrust wedge: inference from numerical modelling. Natural Science, 2, 667-680. doi: 10.4236/ns.2010.27083.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	Ratschbacher, L., Frisch, W., Neubauer, F., Schmid, S.M. and Neugebauer, J. (1989) Extension in compressional orogenic belt: The eastern Alps, Geology, 17(5), 404407.
[2]	Corredor, F. (2003) Eastward extend of the late eocene early oligocene onset of deformation across the northern Andes: constraints from the northern portion of the Eastern Cordillera fold belt, Colombia. Journal of South American Earth Sciences, 16(6), 445457.
[3]	Caiazzo, C., Ascione, A. and Cinque, A. (2006) Late tertiaryquaternary tectonics of the southernapennines (Italy): New evidences from the Tyrrhenian slop. Tectonophysics, 421(12), 2351.
[4]	Norton, M. (1986) Late Caladonian extension in western Norway: A response to extreme crustal thickening. Tectonics, 5(2), 192204.
[5]	Hodges, K.V. and Walker, J.D. (1992) Extension in the cretaceous Sevier Oroben, North American Cordillera. Geology, 104(5), 560569.
[6]	Burg, J.P., Brunel, M., Gapais, D., Chen, G.M. and Liu, G.H. (1984) Deformation of leucogranites of the crystalline main central thrust sheet in southern Tibet (China). Journal of Structural Geology, 6, 219223.
[7]	Royden, L.H. and Burchfiel, B.C. (1987) Thin skinned NS extension within the convergence Himalayan region; Gravitational collapse of a Miocene topographic front. In: Continental Extensional Tectonics, Croward, M.P., Dewey, J.F. and Hanback, P.L., Eds., Geological Society London, 26(56), 611619.
[8]	Hodges, K.V., Parrish, R., Housh, T., Lux, D., Burchfiel, B.C., Royden, L. and Chan, Z. (1992) Simultaneous Miocene extension and shortening in the Himalayan origin. Science, 258(5087), 14661470.
[9]	Gansser, A. (1964) Geology of the Himalayas. Wiley InterScience, New York, 289.
[10]	Molnar, P. and LyonCaen, H. (1988) Some simple physical aspects of the support, structure, and evolution of mountain belts. In: Clark, S., Burchfiel, B.C. and Suppe, J., Eds., Processes in Continental Lithospheric Deformation, Geological Society of America Special Paper, 218, 179207.
[11]	Le Fort, P. (1975) Himalayas, the collided range: Present knowledge of the continental arc. American Journal of Science, 275(A), 144.
[12]	Joshi G.R. and Hayashi, D. (2008b). Numerical modelling of neotectonic movements and state of stresses in the central Seismic Gap region, Garhwal Himalaya. Journal of Mountain Science, 5(4), 279298.
[13]	Hodges, K., Bowring, S., Davidek, K., David Hawkins, D. and Krol, M. (1998) Evidence for rapid displacement on Himalayan normal faults and the importance of tectonic denudation in the evolution of mountain ranges. Geology, 26(6), 483486.
[14]	Nakata, T. (1989) Active faults of Himalaya of India and Nepal. Geological Society of America, 332(1), 243264.
[15]	Mugnier, J.L., Huyghe, P., Chalaron, E. and Mascle, G. (1994) Recent movements along the main boundary thrust of the Himalayas: Normal faulting in an over critical thrust wedge? Tectonophysics, 238(14), 199215.
[16]	Thakur, V.C., Rautela, P. and Jafaruddin, M. (1995) Normal faults in pinjor thrust zone in Lesser Himalaya and between the higher Himalaya Crystallines and Chamba sequence in Kashmir Himalaya, India. Earth Planetary Science, 104(3), 499508.
[17]	Vanney, J., Grasemann, B., Rahn, M., Frank, W., Carter, A., Baudraz, V. and Cosca, M. (2004) Miocene to Holocene exhumation of metamorphic crustal wedges in the NW Himalaya: Evidence for tectonic extrusion coupled to fluvial erosion. Tectonics, 23(1), 124.
[18]	Vanney, J. and Grasemann, B. (2001) Himalayan inverted metamorphism and synconvergence extension as a consequence of a general shear extrusion. Geological Magazine, 138(3), 253276.
[19]	Philips, G. and Virdi, N.S. (2006) Coexisting compressional and extensional regiems along the Himalayan front visàvis active fault near Singhauli, Haryana, India; Active faults and neotectonic activity in the Panjour Dun, Northwestern Frontal Himalaya. Current Science, 90(9), 12671271.
[20]	Vanbrabant, Y, Jongmans, D., Hassani, R. and Bellono, D. (1999) An application of twodimensitional finiteele ment modelling for studying the deformation of the Vriscan foldandthrust belt (Belgium). Tectonophysics, 309(14), 141159.
[21]	Yin, A. (1993) Mechanics of wedge shaped fault blocks an elstic solution for compressional wedge. Journal of Geophysical Research, 98(B8), 1424514256.
[22]	Shankar, D., Kapur, N. and Singh, B. (2002) Thrust wedge mechanics and coeval development of normal and reverse faults in the Himalayas. Journal of Geological Society, 137(1), 134.
[23]	Beaumont, C., Jamieson, R.A., Nguyen, M.H. and Lee, B. (2001) Himalayan tectonics explained by extrusion of a lowviscosity crustal channel coupled to focus surface denudation. Nature, 414(6865), 738742.
[24]	Jamieson, R.A., Beaumont, C., Medvedev, S. and Nguyen, M.H. (2004) Crustal channel flows: Numerical models with implications for metamorphism in the HimalayanTibetan Orogen. Journal of Geophysical Research, 109(B06407), 124.
[25]	Zhao, W., Nelson, K.D. and Team, P.I. (1993) Deep seismic reflection evidence for continental underthrusting beneath southern Tibet. Nature, 366(6455), 557559.
[26]	Schelling, D. and Arita, K. (1991) Thrust tectonics, crus tal shortening and the structure of the far eastern Nepal Himalaya. Tectonics, 10(5), 851862.
[27]	Srivastava, P. and Mitra, G. (1994) Thrust geometries and deep structure of the outer and inner Lesser Himalaya, Kumaun and Garhwal (India): Implications for evolution of the Himalayan foldandthrust belt. Tectonics, 13(1), 89109.
[28]	Pandey, M.R., Tandukar, R.P., Avouac, J.P., Leve, J. and Massot, P. (1995) Interseismic stress accumulation on the Himalayan crustal ramp (Nepal). Geophysical Research Letter, 22(16), 751754.
[29]	Yeats, R.S., Nakata, T., Farah, A., Fort, M., Miza, M.A., Pandey, M.R. and Stein, R.S. (1992) The Himalayan frontal fault system. Annales Tectonicas, 6(Suppl.), 8598.
[30]	Berger, A., Jouanne, F., Hassani, R.D. and Mugnier, J.L. (2004) Modelling the spatial distribution of the presentday deformation in Nepal: How cylindrical is the main Himalayan thrust in Nepal? Geophysical Journal International, 156(1), 94114.
[31]	Searle, M.P., Law, R.D., Godin, L., Larson, K.P., Streule, M.J., Cottle, J.M. and Jessup, M.J. (2008) Defining the Himalayan main central thrust in Nepal. Journal of the Geological Society, 165(2), 523534.
[32]	Meigs, A.J., Douglas, W., Burbank, B. and Beck, A.B. (1995) Middlelate Miocene (> 10 Ma) formation of the main boundary thrust in the western Himalaya. Geology, 23(5), 423426.
[33]	Valdiya, K.S. (2001) Reactivation of terrenedefining boundary thrusts in central sector of the Himalaya: Implications. Current Science, 81(11), 14181431.
[34]	Malik, J.N. and Nakata, T. (2003) Active faults and related late quaternary deformation along the Northwestern Himalayan Frontal zone, India. Analysis of Geophysics, 46(5), 917936.
[35]	Kumar, S., Wesnousky, W.S., Rockwell, T.K., Ragona, D., Thakur, V.C. and Seitz, G. (2001) Earthquake recurrence and rupture dynamics of the Himalayan Frontal thrust, India. Science, 294(5550), 23282331.
[36]	Philip, G. and Sah, M.P. (1999) Geomorphic Signatures for active tectonics in the Trans Yamuna segment of the western Doon Valley, NW Himalaya. International Journal of Applied Earth Observation and Geoinformation, 1(1), 5463.
[37]	Malik, J.N. and Mohanty, C. (2007) Active tectonic influence on the evolution of drainage and landscape: Geomorphic signatures from frontal and hinterland areas along the Northern Himalaya, India. Journal of Asian Earth Sciences, 29(56), 604618.
[38]	Hayashi, D. (2008) Theoretical basis of FE simulation software package. Bulletin Faculty of Science University of the Ryukyus, 85(3), 8195.
[39]	Joshi G.R. and Hayashi D. (2008) Neotectonic deformation and shortening along the Himalayan front in the Garhwal region by finite element modelling. Bullettino di Geofisica Teorica ed Applicacate, 49(Suppl.2), 228233.
[40]	Joshi G.R. and Hayashi, D. (2010). Finite element modelling of the pullapart formation: Implication for tectonics of Bengo Co pullapart basin, Southern Tibet. Natural Science, 2(6), 654666.
[41]	Wang, K., He, J. and Devis, E.E. (1997) Transform puss, oblique subduction resistance, and intraplate stress of the Juan de Fuca plate. Journal of Geophysical Research, 102(B1), 661674.
[42]	Melosh, F.J. and Williams, C.A. (1989) Mechanics of graben formation in crustal rocks: A Finite element ana lysis. Journal of Geophysical Research, 94(B10), 13961 13973.
[43]	Ni, J. and Barazangi, M. (1984) Seismotectonics of the Himalayan collision zone; Geometry of the underthrusting Indian plate beneath the Himalaya. Journal of Geophysical Research, 89(B8), 11471163.
[44]	Bilham, R., Larson, K., Freymueller, J., et al. (1997) GPS measurements of presentday convergence across the Nepal Himalaya. Nature, 386(6620), 6164.
[45]	DeMets, C., Gordon, R.G., Argus, D.F. and Stein, S. (1994) Effect of recent revisions to the geomagnetic reversal time scale on estimates of current plate motions. Geophysical Research Letter, 21(20), 21912194.
[46]	Banerjee, P. and Bürgmann, R. (2002) Convergence across the northwestern Himalaya from GPS measurements. Geophysical Research Letters, 29(20), 3034.
[47]	Wesnousky G.S., Kumar, S., Mohindra, R. and Thakur, V.C. (1999) Uplift and convergence along the Himalayan frontal thrust of India. Tectonics, 18(6), 967976.
[48]	Lave, J. and Avouac, J.P. (2000) Active folding of fluvial terraces across the Siwalik Hills, Himalayas of Central Nepal. Journal of Geophysical Research, 105(B3), 5735 5770.
[49]	Hetényi, G., Cattin, R., Brunet, F., Bollinger, L., VergenJone, J., Nábělek, L. and Diament, M. (2007) Density distribution of the India plate beneath the Tibetan plateau: Geophysical and petrological constraints on the kinetics of lowercrustal eclogitization. Earth and Planetary Science Letter, 264(12), 226244.
[50]	Cotton, F., Compillo, M., Deschamps, A. and Rastogi, B. K. (1996) Rupture history and seismotectonics of the 1991 Uttarkashi, Himalaya earthquake. Tectonophysics, 258(14), 3551.
[51]	Yeats, R. and Thakur, V.C. (1998) Reassessment of earthquake hazard based on a faultbendfold model of the Himalayan plateboundary fault. Current Science, 74(3), 230233.
[52]	Timoshenko, S.P. and Goodier, J.N. (1970) Theory of Elasticity, McGrawHill Book Company, 3rd Edition, London, 567588.
[53]	Clark, S.P., Jr., Ed. (1966) Handbook of Physical Constants, Geological Society America, Memoir, 97, 587.
[54]	Anderson, E.M. (1951) The dynamics of faulting and dike formation with application to Britain. Oliver and Boyd, 2nd Edition, Edinburgh, 133147.
[55]	Dahlen, F.A. and Suppe, J. (1988) Mechanics, growth and erosion of mountain belts. Processes in Continental Lithospheric Deformation, Geological Society of America, 218(12), 161178.
[56]	Patrait, M.R. and Achache, J. (1984) IndiaEurasia collision chronology and its implications for crustal shortening and driving mechanisms of the plates. Nature, 311(18), 615621.
[57]	Nakata, T., Otsuki, K. and Khan, S.H. (1990) Active faults, stress field and plate motion along the IndoEurasian plate boundary. Tectonophysics, 181(14), 8395.
[58]	Wills, S. and Buck, W.R. (1997) Stress field rotation and rooted detachment faults: A coulomb failure analysis. Journal of Geophysical Research, 102(B9), 20503 20514.

Journals Menu

Follow SCIRP

	+1 323-425-8868
	customer@scirp.org
	+86 18163351462(WhatsApp)
	1655362766

	Paper Publishing WeChat

Journals Menu

Home

About SCIRP

Service

Policies