DOCSLIB.ORG

Active Strike-Slip Faults and an Outer Frontal Thrust in the Himalayan Foreland Basin

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Active Strike-Slip Faults and an Outer Frontal Thrust in the Himalayan Foreland Basin Active strike-slip faults and an outer frontal thrust in the Himalayan foreland basin Michael J. Duvalla, John W. F. Waldrona,1, Laurent Godinb, and Yani Najmanc aDepartment of Earth and Atmospheric Sciences, University of Alberta, Edmonton, AB T6G2E3, Canada; bDepartment of Geological Sciences and Geological Engineering, Queen’s University, Kingston ON K7L 3N6, Canada; and cLancaster Environment Centre, Lancaster University, LA1 4YQ Lancaster, United Kingdom Edited by Lisa Tauxe, University of California San Diego, La Jolla, CA, and approved June 11, 2020 (received for review February 2, 2020) The Himalayan foreland basin formed by flexure of the Indian Plate unconformably on Proterozoic mobile belts, sedimentary basins, below the advancing orogen. Motion on major thrusts within the and an Archean craton, exposed along the southern edge of the orogen has resulted in damaging historical seismicity, whereas south basin. The stratigraphy of the basin is known from drilling and of the Main Frontal Thrust (MFT), the foreland basin is typically from outcrop in the sub-Himalaya and Lesser Himalaya (22). portrayed as undeformed. Using two-dimensional seismic reflection The basin fill is divided by an Oligocene disconformity in the sub- data from eastern Nepal, we present evidence of recent deformation Himalaya (23, 24), below which a thin (>90 m) Paleogene suc- propagating >37 km south of the MFT. A system of tear faults at a cession is dominated by marine mudstone (25). The overlying high angle to the orogen is spatially localized above the Munger- Miocene to Quaternary rocks are fluvial deposits that filled the Saharsa basement ridge. A blind thrust fault is interpreted in the subsiding basin (4). This package comprises the Siwalik Group subsurface, above the sub-Cenozoic unconformity, bounded by two and the thinner, underlying, Dumri Formation. Seismic reflec- tear faults. Deformation zones beneath the Bhadrapur topographic tions, corresponding approximately to the lithological bound- high record an incipient tectonic wedge or triangle zone. The faults aries between the lower, middle, and upper Siwalik Group, record the subsurface propagation of the Main Himalayan Thrust identified in the log of the Biratnagar-1 well (Fig. 2), are traced (MHT) into the foreland basin as an outer frontal thrust, and provide through two-dimensional (2D) industry seismic data; the well is a modern snapshot of the development of tectonic wedges and lat- not deep enough to allow us to pick the Oligocene disconformity, eral discontinuities preserved in higher thrust sheets of the Himalaya, but the deeper, angular sub-Cenozoic unconformity, represent- and in ancient orogens elsewhere. We estimate a cumulative slip of ing the base of the foreland basin deposits, was traced. Locally EARTH, ATMOSPHERIC, AND PLANETARY SCIENCES ∼100 m, accumulated in <0.5 Ma, over a minimum slipped area of we identified a deeper horizon marking the top of unstratified ∼780 km2. These observations demonstrate that Himalayan ruptures acoustic basement. Regional variations in the thickness of the may pass under the present-day trace of the MFT as blind faults in- Siwalik Group are controlled by a series of basement ridges (11), accessible to trenching, and that paleoseismic studies may transverse to the orogen, of which the easternmost, Munger– underestimate Holocene convergence. Saharsa ridge, underlies the area of this study (Fig. 1). The – Himalaya | thrust fault | foreland basin | seismicity Munger Saharsa ridge, like other basement ridges beneath the basin, appears to be defined by NE-SW–striking faults (11) that bound Proterozoic to Paleozoic grabens beneath the foreland he Himalayan orogen, the Earth’s highest mountain range, is > – basin and are locally sources of earthquakes at depths 30 km Ta product of ongoing continent continent collision between (e.g., ref. 26). Rare events well to the south of the foreland basin India and Asia (Fig. 1). The orogen is subdivided into longitu- show normal-sense focal mechanisms (Fig. 1) but close to the dinally continuous lithotectonic domains, bounded by continent- scale faults (1, 2). The southernmost fault, the Main Frontal Significance Thrust (MFT), separates the Himalayan foreland basin, typically regarded as undeformed, from the sub-Himalaya, composed of thrusted and folded foreland basin sedimentary rocks (3, 4). We The Himalayan mountain belt results from continuing conver- show that a previously unknown blind thrust and a series of gence between the Indian Plate and Asia. Damaging earth- strike-slip tear faults propagate southward into the Himalayan quakes occur on major thrust faults north of the Main Frontal foreland basin up to 37 km south of the MFT in eastern Nepal, Thrust (MFT). To the south, the Ganga foreland basin is typi- forming an isolated topographic feature, the Bhadrapur High cally described as undeformed. We show that active thrust and strike-slip faults, with accumulated slip up to ∼100 m, pass that rises ∼60 m above the surrounding plain (Fig. 2). We esti- under the trace of the MFT into the foreland basin in eastern mate slip along this incipient thrust system, and discuss the im- Nepal, leading to propagation of deformation at least ∼37 km plications for the development of structure in the Himalaya and into the foreland basin beneath the densely populated Ganga for its seismicity. plain. The development of these faults at the active thrust North of the MFT, the sub-Himalaya shows lateral changes in front helps to explain structures preserved in higher thrust structure along strike, resulting in variations in thrust vergence sheets of the Himalaya, and in ancient mountain belts and the preservation of piggyback basins (15). Farther north, the elsewhere. Main Boundary Thrust (MBT) and Main Central Thrust (MCT) bound the Lesser and Greater Himalaya, respectively, in which a Author contributions: J.W.F.W., L.G., and Y.N. designed research; M.J.D. performed re- series of along-strike culminations and depressions locally lead search; M.J.D., J.W.F.W., and Y.N. analyzed data; and M.J.D., J.W.F.W., and L.G. wrote to the preservation of fenster and klippen (16). These major the paper. thrusts root at depth on the Main Himalayan Thrust (MHT), a The authors declare no competing interest. crustal-scale detachment (17–20) above autochthonous Indian This article is a PNAS Direct Submission. basement. Lateral segmentation is also evident in the episodic Published under the PNAS license. occurrence of seismic slip on the major thrust faults (21). 1To whom correspondence may be addressed. Email: [email protected]. South of the MFT, the Ganga Basin (Fig. 1) is the Himalayan This article contains supporting information online at https://www.pnas.org/lookup/suppl/ foreland basin (Fig. 1A) in Nepal and northern India. The basin doi:10.1073/pnas.2001979117/-/DCSupplemental. is filled (4) by 3 to >7 km of sedimentary rock that rests www.pnas.org/cgi/doi/10.1073/pnas.2001979117 PNAS Latest Articles | 1of7 Downloaded by guest on September 29, 2021 STD Tethyan Himalaya Shillong Plateau gneissic complex A MCT Greater Himalaya Chotanagpur gneissic complex Major city Lesser Himalaya MBT Satpura mobile belt Basement fault Indus MFT Sub-Himalaya Bundelkhand Craton Seismic survey Basin Quaternary sediments Nepal Aravalli-Delhi fold belt 22 Late Cretaceous volcanic rocks Focal mechanism with depth (km) Gondwanan sedimentary rocks Other units Ganga Basin Proterozoic Vindhyan succession Basement ridges Well location 28 India B 74° MFT 80° ITSZ 15 10 Bengal MCT 17 21 10 Basin 15 12 15 13 16 15 STD 15 N 12 15 15 22 15 15 34 10 19 15 New Delhi 33 28° 21 12 12 MBT 46 12 20 Delhi-Haridwar Ridge 44 Kathmandu 21 MFT 35 Faizabad Block 10 Ridge Munger- Saharsa Ridge 24° 200 km 38 Kolkata Fig. 1. Location maps. (A) Generalized map of the Himalaya showing principal Neogene basins. Image credit: Google Earth. © 2019 TerraMetrics, map data © 2019 used with permission. (B) Map of northern India, Nepal, and adjacent areas, from published sources (2, 5–10) and US Geological Survey public data. Approximate traces of basement ridges after Godin and Harris (11). ITSZ: Indus-Tsangpo Suture Zone; STD: South Tibet Detachment. Focal mechanisms and depths (kilometers) are derived from the Global Centroid Moment Tensor Project (12, 13) shown for seismic events with moment magnitude Mw > 5.5 during the period 1976–2019, plotted with the aid of GMT software (14). Box encloses area of Fig. 4C. MFT, and beneath the Himalaya, these faults appear to be vertical faults are typically inferred at discontinuities in the reactivated in sinistral strike-slip (5, 26–29). poorly coherent reflections. Folds may be differentiated as Faults and folds within the overlying sedimentary package of contractional or extensional, based on the upwarp or downwarp the Ganga Basin are uncommon, with the result that most strata of mapped horizons relative to their regional structural level. lie flat and undisturbed. The foreland basin is thus commonly Correlated between profiles, the faults are traced up to 37 km, presented as undeformed, despite the occurrence of earthquakes showing two main strike orientations: ∼NNE-SSW and ∼NNW- (30), river migration patterns that indicate active tectonic con- SSE. However, the faults show distinct bends when traced along trols (31), and enigmatic topographic features such as the Bha- their strike (Fig. 2) that coincide with changes between con- drapur high in southeast Nepal (Fig. 2), which is identified as a traction and extension. We therefore interpret them as strike-slip doubly plunging anticline in existing geologic maps (32). faults. The transitions from contraction to extension in the ad- jacent damage zones (Fig. 2) allow us to identify bends in the Results fault traces as restraining or releasing, and therefore to charac- Using 2D seismic reflection data provided by Cairn Energy, we terize the faults as sinistral or dextral (Fig.
Load more

Recommended publications
  • Introduction San Andreas Fault: an Overview
    Introduction This volume is a general geology field guide to the San Andreas Fault in the San Francisco Bay Area. The first section provides a brief overview of the San Andreas Fault in context to regional California geology, the Bay Area, and earthquake history with emphasis of the section of the fault that ruptured in the Great San Francisco Earthquake of 1906. This first section also contains information useful for discussion and making field observations associated with fault- related landforms, landslides and mass-wasting features, and the plant ecology in the study region. The second section contains field trips and recommended hikes on public lands in the Santa Cruz Mountains, along the San Mateo Coast, and at Point Reyes National Seashore. These trips provide access to the San Andreas Fault and associated faults, and to significant rock exposures and landforms in the vicinity. Note that more stops are provided in each of the sections than might be possible to visit in a day. The extra material is intended to provide optional choices to visit in a region with a wealth of natural resources, and to support discussions and provide information about additional field exploration in the Santa Cruz Mountains region. An early version of the guidebook was used in conjunction with the Pacific SEPM 2004 Fall Field Trip. Selected references provide a more technical and exhaustive overview of the fault system and geology in this field area; for instance, see USGS Professional Paper 1550-E (Wells, 2004). San Andreas Fault: An Overview The catastrophe caused by the 1906 earthquake in the San Francisco region started the study of earthquakes and California geology in earnest.
    [Show full text]
  • Flexural Modeling of the Himalayan Foreland Basin: Implications for the Presence of a Forebulge and Formation of Basement Ridges
    FLEXURAL MODELING OF THE HIMALAYAN FORELAND BASIN: IMPLICATIONS FOR THE PRESENCE OF A FOREBULGE AND FORMATION OF BASEMENT RIDGES __________________________________ An Abstract of a Thesis Presented to the Faculty of the Department of Earth and Atmospheric Sciences University of Houston __________________________________ In Partial Fulfillment of the Requirements for the Degree Master of Science __________________________________ By Nicole F. Arres August 2013 FLEXURAL MODELING OF THE HIMALAYAN FORELAND BASIN: IMPLICATIONS FOR THE PRESENCE OF A FOREBULGE AND FORMATION OF BASEMENT RIDGES ____________________________________________________ Nicole F. Arres APPROVED: ____________________________________________________ Dr. Jolante van Wijk, Advisor ____________________________________________________ Dr. Michael Murphy ____________________________________________________ Dr. Peter Copeland ____________________________________________________ Dr. An Yin University of California at Los Angeles ____________________________________________________ Dean, College of Natural Sciences and Mathematics ii FLEXURAL MODELING OF THE HIMALAYAN FORELAND BASIN: IMPLICATIONS FOR THE PRESENCE OF A FOREBULGE AND FORMATION OF BASEMENT RIDGES __________________________________ An Abstract of a Thesis Presented to the Faculty of the Department of Earth and Atmospheric Sciences University of Houston __________________________________ In Partial Fulfillment of the Requirements for the Degree Master of Science __________________________________ By Nicole F. Arres
    [Show full text]
  • Characterizing the Main Himalayan Thrust in the Garhwal Himalaya, India with Receiver Function CCP Stacking
    Earth and Planetary Science Letters 367 (2013) 15–27 Contents lists available at SciVerse ScienceDirect Earth and Planetary Science Letters journal homepage: www.elsevier.com/locate/epsl Characterizing the Main Himalayan Thrust in the Garhwal Himalaya, India with receiver function CCP stacking Warren B. Caldwell a,n, Simon L. Klemperer a, Jesse F. Lawrence a, Shyam S. Rai b, Ashish c a Stanford University, Stanford, CA, United States b National Geophysical Research Institute, Hyderabad, India c CSIR Centre for Mathematical Modeling and Computer Simulation, NAL Belur, Bangalore, India article info abstract Article history: We use common conversion point (CCP) stacking of Ps receiver functions to image the crustal structure Received 20 November 2012 and Moho of the Garhwal Himalaya of India. Our seismic array of 21 broadband seismometers spanned Received in revised form the Himalayan thrust wedge at 79–801E, between the Main Frontal Thrust and the South Tibet 10 February 2013 Detachment, in 2005–2006. Our CCP image shows the Main Himalayan Thrust (MHT), the detachment Accepted 11 February 2013 at the base of the Himalayan thrust wedge, with a flat-ramp-flat geometry. Seismic impedance Editor: T.M. Harrison contrasts inferred from geologic cross-sections in Garhwal imply a negative impedance contrast (velocity decreasing downward) for the upper flat, located beneath the Lower Himalaya, and a positive Keywords: impedance contrast (velocity increasing downward) for the ramp, located beneath the surface trace of Himalaya the Munsiari Thrust (or MCT-I). At the lower flat, located beneath the Higher Himalaya, spatially India coincident measurements of very high electrical conductivities require the presence of free fluids, and Garhwal receiver functions we infer a negative impedance contrast on the MHT caused by ponding of these fluids beneath the CCP stacking detachment.
    [Show full text]
  • Present Day Plate Boundary Deformation in the Caribbean and Crustal Deformation on Southern Haiti Steeve Symithe Purdue University
    Purdue University Purdue e-Pubs Open Access Dissertations Theses and Dissertations 4-2016 Present day plate boundary deformation in the Caribbean and crustal deformation on southern Haiti Steeve Symithe Purdue University Follow this and additional works at: https://docs.lib.purdue.edu/open_access_dissertations Part of the Caribbean Languages and Societies Commons, Geology Commons, and the Geophysics and Seismology Commons Recommended Citation Symithe, Steeve, "Present day plate boundary deformation in the Caribbean and crustal deformation on southern Haiti" (2016). Open Access Dissertations. 715. https://docs.lib.purdue.edu/open_access_dissertations/715 This document has been made available through Purdue e-Pubs, a service of the Purdue University Libraries. Please contact [email protected] for additional information. Graduate School Form 30 Updated ¡ ¢¡£ ¢¡¤ ¥ PURDUE UNIVERSITY GRADUATE SCHOOL Thesis/Dissertation Acceptance This is to certify that the thesis/dissertation prepared By Steeve Symithe Entitled Present Day Plate Boundary Deformation in The Caribbean and Crustal Deformation On Southern Haiti. For the degree of Doctor of Philosophy Is approved by the final examining committee: Christopher L. Andronicos Chair Andrew M. Freed Julie L. Elliott Ayhan Irfanoglu To the best of my knowledge and as understood by the student in the Thesis/Dissertation Agreement, Publication Delay, and Certification Disclaimer (Graduate School Form 32), this thesis/dissertation adheres to the provisions of Purdue University’s “Policy of Integrity in Research” and the use of copyright material. Andrew M. Freed Approved by Major Professor(s): Indrajeet Chaubey 04/21/2016 Approved by: Head of the Departmental Graduate Program Date PRESENT DAY PLATE BOUNDARY DEFORMATION IN THE CARIBBEAN AND CRUSTAL DEFORMATION ON SOUTHERN HAITI A Dissertation Submitted to the Faculty of Purdue University by Steeve J.
    [Show full text]
  • Himalaya - Southern-Tibet: the Typical Continent-Continent Collision Orogen
    237 Himalaya - Southern-Tibet: the typical continent-continent collision orogen When an oceanic plate is subducted beneath a continental lithosphere, an Andean mountain range develops on the edge of the continent. If the subducting plate also contains some continental lithosphere, plate convergence eventually brings both continents into juxtaposition. While the oceanic lithosphere is relatively dense and sinks into the asthenosphere, the greater sialic content of the continental lithosphere ascribes positive buoyancy in the asthenosphere, which hinders the continental lithosphere to be subducted any great distance. Consequently, a continental lithosphere arriving at a trench will confront the overriding continent. Rapid relative convergence is halted and crustal shortening forms a collision mountain range. The plane marking the locus of collision is a suture, which usually preserves slivers of the oceanic lithosphere that formerly separated the continents, known as ophiolites. The collision between the Indian subcontinent and what is now Tibet began in the Eocene. It involved and still involves north-south convergence throughout southern Tibet and the Himalayas. This youthful mountain area is the type example for studies of continental collision processes. The Himalayas Location The Himalayas form a nearly 3000 km long, 250-350 km wide range between India to the south and the huge Tibetan plateau, with a mean elevation of 5000 m, to the north. The Himalayan mountain belt has a relatively simple, arcuate, and cylindrical geometry over most of its length and terminates at both ends in nearly transverse syntaxes, i.e. areas where orogenic structures turn sharply about a vertical axis. Both syntaxes are named after the main peaks that tower above them, the Namche Barwa (7756 m) to the east and the Nanga Parbat (8138 m) to the west, in Pakistan.
    [Show full text]
  • Composition, Alteration, and Texture of Fault-Related Rocks from Safod Core and Surface Outcrop Analogs
    Pure Appl. Geophys. Ó 2014 Springer Basel DOI 10.1007/s00024-014-0896-6 Pure and Applied Geophysics Composition, Alteration, and Texture of Fault-Related Rocks from Safod Core and Surface Outcrop Analogs: Evidence for Deformation Processes and Fluid-Rock Interactions 1 1 1 1 1 KELLY K. BRADBURY, COLTER R. DAVIS, JOHN W. SHERVAIS, SUSANNE U. JANECKE, and JAMES P. EVANS Abstract—We examine the fine-scale variations in mineralogi- 1. Introduction cal composition, geochemical alteration, and texture of the fault- related rocks from the Phase 3 whole-rock core sampled between 3,187.4 and 3,301.4 m measured depth within the San Andreas Fault Well-constrained geological, geochemical, and Observatory at Depth (SAFOD) borehole near Parkfield, California. geophysical models of active fault zones are needed if This work provides insight into the physical and chemical properties, we are to understand fault zone behavior and earth- structural architecture, and fluid-rock interactions associated with the actively deforming traces of the San Andreas Fault zone at depth. quake deformation, constraining the factors that affect Exhumed outcrops within the SAF system comprised of serpentinite- the distribution of earthquakes, and the nature of slip bearing protolith are examined for comparison at San Simeon, Goat in the shallow crust by developing realistic models of Rock State Park, and Nelson Creek, California. In the Phase 3 SAFOD drillcore samples, the fault-related rocks consist of multiple subsurface fault zone structure and ground motion juxtaposed lenses of sheared, foliated siltstone and shale with block- predictions. Earthquakes nucleate in rocks at depth in-matrix fabric, black cataclasite to ultracataclasite, and sheared (e.g., FAGERENG and TOY 2011;SIBSON 1977; 2003), serpentinite-bearing, finely foliated fault gouge.
    [Show full text]
  • A GPS and Modelling Study of Deformation in Northern Central America
    Geophys. J. Int. (2009) 178, 1733–1754 doi: 10.1111/j.1365-246X.2009.04251.x A GPS and modelling study of deformation in northern Central America M. Rodriguez,1 C. DeMets,1 R. Rogers,2 C. Tenorio3 and D. Hernandez4 1Geology and Geophysics, University of Wisconsin-Madison, Madison, WI 53706 USA. E-mail: [email protected] 2Department of Geology, California State University Stanislaus, Turlock, CA 95382,USA 3School of Physics, Faculty of Sciences, Universidad Nacional Autonoma de Honduras, Tegucigalpa, Honduras 4Servicio Nacional de Estudios Territoriales, Ministerio de Medio Ambiente y Recursos Naturales, Km. 5 1/2 carretera a Santa Tecla, Colonia y Calle Las Mercedes, Plantel ISTA, San Salvador, El Salvador Accepted 2009 May 9. Received 2009 May 8; in original form 2008 August 15 SUMMARY We use GPS measurements at 37 stations in Honduras and El Salvador to describe active deformation of the western end of the Caribbean Plate between the Motagua fault and Central American volcanic arc. All GPS sites located in eastern Honduras move with the Caribbean Plate, in accord with geologic evidence for an absence of neotectonic deformation in this region. Relative to the Caribbean Plate, the other stations in the study area move west to west–northwest at rates that increase gradually from 3.3 ± 0.6 mm yr−1 in central Honduras to 4.1 ± 0.6 mm yr−1 in western Honduras to as high as 11–12 mm yr−1 in southern Guatemala. The site motions are consistent with slow westward extension that has been inferred by previous authors from the north-striking grabens and earthquake focal mechanisms in this region.
    [Show full text]
  • Contractional Tectonics: Investigations of Ongoing Construction of The
    Louisiana State University LSU Digital Commons LSU Doctoral Dissertations Graduate School 2014 Contractional Tectonics: Investigations of Ongoing Construction of the Himalaya Fold-thrust Belt and the Trishear Model of Fault-propagation Folding Hongjiao Yu Louisiana State University and Agricultural and Mechanical College, [email protected] Follow this and additional works at: https://digitalcommons.lsu.edu/gradschool_dissertations Part of the Earth Sciences Commons Recommended Citation Yu, Hongjiao, "Contractional Tectonics: Investigations of Ongoing Construction of the Himalaya Fold-thrust Belt and the Trishear Model of Fault-propagation Folding" (2014). LSU Doctoral Dissertations. 2683. https://digitalcommons.lsu.edu/gradschool_dissertations/2683 This Dissertation is brought to you for free and open access by the Graduate School at LSU Digital Commons. It has been accepted for inclusion in LSU Doctoral Dissertations by an authorized graduate school editor of LSU Digital Commons. For more information, please [email protected]. CONTRACTIONAL TECTONICS: INVESTIGATIONS OF ONGOING CONSTRUCTION OF THE HIMALAYAN FOLD-THRUST BELT AND THE TRISHEAR MODEL OF FAULT-PROPAGATION FOLDING A Dissertation Submitted to the Graduate Faculty of the Louisiana State University and Agricultural and Mechanical College in partial fulfillment of the requirements for the degree of Doctor of Philosophy in The Department of Geology and Geophysics by Hongjiao Yu B.S., China University of Petroleum, 2006 M.S., Peking University, 2009 August 2014 ACKNOWLEDGMENTS I have had a wonderful five-year adventure in the Department of Geology and Geophysics at Louisiana State University. I owe a lot of gratitude to many people and I would not have been able to complete my PhD research without the support and help from them.
    [Show full text]
  • Collision Orogeny
    Downloaded from http://sp.lyellcollection.org/ by guest on October 6, 2021 PROCESSES OF COLLISION OROGENY Downloaded from http://sp.lyellcollection.org/ by guest on October 6, 2021 Downloaded from http://sp.lyellcollection.org/ by guest on October 6, 2021 Shortening of continental lithosphere: the neotectonics of Eastern Anatolia a young collision zone J.F. Dewey, M.R. Hempton, W.S.F. Kidd, F. Saroglu & A.M.C. ~eng6r SUMMARY: We use the tectonics of Eastern Anatolia to exemplify many of the different aspects of collision tectonics, namely the formation of plateaux, thrust belts, foreland flexures, widespread foreland/hinterland deformation zones and orogenic collapse/distension zones. Eastern Anatolia is a 2 km high plateau bounded to the S by the southward-verging Bitlis Thrust Zone and to the N by the Pontide/Minor Caucasus Zone. It has developed as the surface expression of a zone of progressively thickening crust beginning about 12 Ma in the medial Miocene and has resulted from the squeezing and shortening of Eastern Anatolia between the Arabian and European Plates following the Serravallian demise of the last oceanic or quasi- oceanic tract between Arabia and Eurasia. Thickening of the crust to about 52 km has been accompanied by major strike-slip faulting on the rightqateral N Anatolian Transform Fault (NATF) and the left-lateral E Anatolian Transform Fault (EATF) which approximately bound an Anatolian Wedge that is being driven westwards to override the oceanic lithosphere of the Mediterranean along subduction zones from Cephalonia to Crete, and Rhodes to Cyprus. This neotectonic regime began about 12 Ma in Late Serravallian times with uplift from wide- spread littoral/neritic marine conditions to open seasonal wooded savanna with coiluvial, fluvial and limnic environments, and the deposition of the thick Tortonian Kythrean Flysch in the Eastern Mediterranean.
    [Show full text]
  • Modeling Crustal Deformation Near Active Faults and Volcanic Centers—A Catalog of Deformation Models
    Modeling Crustal Deformation near Active Faults and Volcanic Centers—A Catalog of Deformation Models Chapter 1 of Section B, Modeling of Volcanic Processes Book 13, Volcanic Monitoring Techniques and Methods 13–B1 U.S. Department of the Interior U.S. Geological Survey Modeling Crustal Deformation near Active Faults and Volcanic Centers—A Catalog of Deformation Models By Maurizio Battaglia, Peter F. Cervelli, and Jessica R. Murray Chapter 1 of Section B, Modeling of Volcanic Processes Book 13, Volcanic Monitoring Techniques and Methods 13-B1 U.S. Department of the Interior U.S. Geological Survey U.S. Department of the Interior SALLY JEWELL, Secretary U.S. Geological Survey Suzette M. Kimball, Acting Director U.S. Geological Survey, Reston, Virginia: 2013 For more information on the USGS—the Federal source for science about the Earth, its natural and living resources, natural hazards, and the environment, visit http://www.usgs.gov or call 1–888–ASK–USGS. For an overview of USGS information products, including maps, imagery, and publications, visit http://www.usgs.gov/pubprod To order this and other USGS information products, visit http://store.usgs.gov Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government. Although this information product, for the most part, is in the public domain, it also may contain copyrighted materials as noted in the text. Permission to reproduce copyrighted items must be secured from the copyright owner. Suggested citation: Battaglia, Maurizio, Cervelli, P.F., and Murray, J.R., 2013, Modeling crustal deformation near active faults and volcanic centers—A catalog of deformation models: U.S.
    [Show full text]
  • Himalayan Megathrust Geometry and Relation to Topography Revealed by the Gorkha Earthquake J
    ARTICLES PUBLISHED ONLINE: 11 JANUARY 2016 | DOI: 10.1038/NGEO2623 Himalayan megathrust geometry and relation to topography revealed by the Gorkha earthquake J. R. Elliott1*, R. Jolivet2†, P. J. González3, J.-P. Avouac2,4, J. Hollingsworth5, M. P. Searle6 and V. L. Stevens4 The Himalayan mountain range has been the locus of some of the largest continental earthquakes, including the 2015 magnitude 7.8 Gorkha earthquake. Competing hypotheses suggest that Himalayan topography is sustained and plate convergence is accommodated either predominantly on the main plate boundary fault, or more broadly across multiple smaller thrust faults. Here we use geodetic measurements of surface displacement to show that the Gorkha earthquake ruptured the Main Himalayan Thrust fault. The earthquake generated about 1 m of uplift in the Kathmandu Basin, yet caused the high Himalaya farther north to subside by about 0.6 m. We use the geodetic data, combined with geologic, geomorphological and geophysical analyses, to constrain the geometry of the Main Himalayan Thrust in the Kathmandu area. Structural analyses together with interseismic and coseismic displacements are best explained by a steep, shallow thrust fault flattening at depth between 5 and 15 km and connecting to a mid-crustal, steeper thrust. We suggest that present-day convergence across the Himalaya is mostly accommodated by this fault—no significant motion on smaller thrust faults is required. Furthermore, given that the Gorkha earthquake caused the high Himalayan mountains to subside and that our fault geometry explains measured interseismic displacements, we propose that growth of Himalayan topography may largely occur during the ongoing post- seismic phase.
    [Show full text]
  • Early Himalayan Exhumation: Isotopic Constraints from the Indian Foreland
    Paper 268 Disc Early Himalayan exhumation: Isotopic constraints from the Indian foreland basin Yani Najman{,{, Mike Bickle*,{ and Hazel Chapman{ {Department of Earth Sciences, Cambridge University, Downing St., Cambridge CB2 3EQ, UK, {Department of Geology & Geophysics, Edinburgh University, West Mains Road, Edinburgh EH9 3JW, UK ABSTRACT Nd- and Sr-isotopic compositions of Palaeogene foreland basin at least this time until the present day. The transition is sediments are used to provide insights into early Himalayan interpreted to reflect exhumation of `basement rocks' of the evolution,particularly the timing of exposure of high 87Sr/86Sr Indian plate,when the High Himalaya became a sufficient units,erosion of which may have caused the late Tertiary increase topographic barrier to separate suture zone rocks from the in oceanic Sr-isotopic ratios. During the late Palaeocene±early foreland basin. The marked rise in seawater 87Sr/86Sr from 40 Ma Eocene,erosion was from mixed sources including suture zone is consistent with the erosion of a Himalayan source with a high rocks. Exhumation of the High Himalaya was occurring by the 87Sr/86Sr ratio. time of deposition of alluvial sediments after mid-Oligocene times and this source has dominated Himalayan sediments from Terra Nova, 12, 28±34, 2000 chain from six main tectonic units (Fig. cambrian to early Permian and mainly Introduction 1) (listed from north to south below). shelf carbonate in the late Permian to The Himalayas are the prime example 1 The Trans-Himalayan zone,the An- early Eocene,unconformably overlain of an active collisional orogen. Their dean-type northern margin of Tethys by the Chulung La collisional deposits kinematics form the basis of our under- formed by Cretaceous to Eocene calc- (Critelli and Garzanti,1994; Searle et standing of crustal deformation pro- alkaline plutons intruding the Eurasian al.,1997a).
    [Show full text]