LEADER 08580nam 2200505 450 001 9910735567003321 005 20230807193805.0 010 $a1-394-22858-9 010 $a1-394-22856-2 035 $a(MiAaPQ)EBC7269055 035 $a(Au-PeEL)EBL7269055 035 $a(BIP)093489166 035 $a(EXLCZ)9927531924900041 100 $a20230807d2023 uy 0 101 0 $aeng 135 $aurcnu|||||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 00$aHimalaya, dynamics of a giant 1 $eGeodynamic setting of the Himalayan range /$fRodolphe Cattin, Jean-Luc Epard 205 $aFirst edition. 210 1$aLondon, England :$cISTE Ltd and John Wiley & Sons, Inc.,$d[2023] 210 4$d©2023 215 $a1 online resource (301 pages) 311 08$aPrint version: Cattin, Rodolphe Himalaya: Dynamics of a Giant, Geodynamic Setting of the Himalayan Range Newark : John Wiley & Sons, Incorporated,c2023 9781789451290 320 $aIncludes bibliographical references and index. 327 $aCover -- Title Page -- Copyright Page -- Contents -- Tributes -- Foreword -- Preface. From Research to Education: The Example of the Seismology at School in Nepal Program -- Part 1. Tectonic Framework of the Himalaya and Tibet -- Chapter 1. Plate Reconstructions and Mantle Dynamics Leading to the India-Asia Collision -- 1.1. Introduction -- 1.2. The India-Asia convergence and the age of the collision -- 1.2.1.The India-Asia convergence -- 1.2.2. The age of the India-Asia collision -- 1.3. Plate collision configurations -- 1.3.1. Reconstructing lost continental margins -- 1.3.2. Alternative collision configurations -- 1.4. Reconstruction of the Neotethys Ocean closure dynamic -- 1.4.1. Number of subduction accommodating the Neotethys closure -- 1.4.2. Location of the Intraoceanic subduction zone and associated arc -- 1.4.3. Driving forces of the India-Asia convergence during Neotethys closure -- 1.5.Conclusion -- 1.6.References -- Chapter 2. Building the Tibetan Plateau During the Collision Between the India and Asia Plates -- 2.1. Introduction -- 2.2.Present-dayTibetan crustal deformation -- 2.2.1. GPS velocity field and focal mechanisms in Tibet -- 2.2.2. Surface motions and deformation due to Indian indentation -- 2.3. Tibetan lithospheric mantle subduction during collision -- 2.3.1. Imaging ongoing subduction beneath Tibet -- 2.3.2. Imaging subduction of lithospheric Tibetan mantle during the collision -- 2.3.3. Volcanism in Tibet showing the subduction of lithospheric Asian mantle during the early collision -- 2.4. Modeling the Tibetan plateau formation during the indentation of the Indiancontinent intoAsia -- 2.4.1. Analogue modeling of the Tibetan lithosphere subduction duringthe indentationof India -- 2.4.2. Numerical modeling of Asian thickening and extrusion during the subduction of a continental-oceanic plate -- 2.5.Conclusion. 327 $a2.6.References -- Chapter 3. The Major Thrust Faults and Shear Zones -- 3.1. Introduction -- 3.2.Some basic concepts -- 3.3.Main faults andshear zones -- 3.3.1. South Tibetan detachment system (STDS) -- 3.3.2.MainCentral thrust (MCT) -- 3.3.3. Main Boundary thrust (MBT) -- 3.3.4.MainFrontal thrust (MFT) -- 3.3.5. Main Himalayan thrust (MHT), continental megathrust -- 3.4.Tectonicmodels -- 3.4.1. Fold-and-thrust belt versus channel flow -- 3.4.2.Coeval slip along theSTDSand theMCT -- 3.5.Conclusion -- 3.6.References -- Part 2. Along Strike Variations -- Chapter 4. Seismological Imaging and Current Seismicity of the Himalayan Arc -- 4.1. Introduction -- 4.2. Imagingby elasticwaves -- 4.2.1.Active seismics -- 4.2.2.Passive seismics -- 4.2.3. Tomographic imaging for bulk properties -- 4.2.4.Wave reflections and conversions for interfaces -- 4.3. Exploring the Central Himalaya along cross-sections -- 4.3.1.Field experiments -- 4.3.2. Main interfaces -- 4.3.3.Where do subducted plates go? -- 4.4.Lateral variations -- 4.4.1. Lateral ramps on the MHT, along-arcMoho variations -- 4.4.2. Segmentation of the India plate lithosphere -- 4.4.3.Thewestern andeastern syntaxes -- 4.5.Current seismicity of theHimalaya -- 4.5.1. Earthquake detection, location and activity -- 4.5.2. Seismicity of the Himalaya: an incomplete patchwork -- 4.5.3.Seismicity of theHimalaya:main features -- 4.6.Conclusion -- 4.7.References -- Chapter 5. Gravity Observations and Models Along the Himalayan Arc -- 5.1. Introduction -- 5.2. Methods -- 5.2.1. Measurements -- 5.2.2.Corrections -- 5.2.3.Anomalies -- 5.3. Isostasy -- 5.3.1.Local compensation -- 5.3.2.Regional compensation -- 5.3.3.Effectiveelastic thickness -- 5.4.Flexure of the Indianplate -- 5.4.1. Gravity anomaly across the Himalayan belt -- 5.4.2. Along-strike variation between Nepal and Bhutan -- 5.5. Satellite data contribution. 327 $a5.5.1.Gravitymeasurements fromspace -- 5.5.2. Towards a three-dimensional image -- 5.6.Conclusion -- 5.7.References -- Chapter 6. Topographic and Thermochronologic Constraints on the Himalayan Décollement Geometry -- 6.1. Introduction -- 6.2. Methods -- 6.2.1. Quantitative geomorphic analysis -- 6.2.2. Measures of erosion at different timescales: cosmogenic nuclides and thermochronology -- 6.2.3. From exhumation to kinematics: thermo-kinematic models -- 6.3.Regional case studies -- 6.3.1.CentralHimalaya-Nepal -- 6.4.Discussion -- 6.4.1. Constraints on MHT geometry and kinematics at different timescales -- 6.4.2.Nature and evolutionof rampson theMHT -- 6.4.3. Evidence for out-of-sequence thrusting? -- 6.4.4.Lateral segmentationof theMHT -- 6.5.Conclusion -- 6.6.References -- Part 3. Focus -- Chapter 7. Application of Near-surface Geophysical Methods for Imaging Active Faults in the Himalaya -- 7.1. Introduction -- 7.2. Near-surface geophysics -- 7.2.1. Geophysical methods for fault mapping -- 7.2.2. Case study data and inversion technique -- 7.3. Geophysical results of case study from south Bhutan -- 7.3.1.Electrical resistivity tomography -- 7.3.2.Seismic tomography -- 7.3.3.Micro-gravity -- 7.4. Implications of near-surface geophysical findings -- 7.4.1.Subsurface imaging -- 7.4.2.Overthrustingslip rate assessment -- 7.4.3. Deformation at the topographic front -- 7.5.Conclusion -- 7.6.References -- Chapter 8. Overview of Hydrothermal Systems in the Nepal Himalaya -- 8.1. Introduction -- 8.2. Measurement methods -- 8.2.1.Explorationapproach -- 8.2.2.Thermal springwatermeasurements -- 8.2.3. CO2 flux and radonfluxmeasurements -- 8.2.4. Carbon content and isotopic composition measurements -- 8.3. Summary of results at the hydrothermal sites in the Nepal Himalaya -- 8.3.1. Overview of hydrothermal sites in Far-Western Nepal. 327 $a8.3.2. Overview of hydrothermal sites in Mid-Western Nepal -- 8.3.3. Overview of hydrothermal sites in Western Nepal -- 8.3.4. Overview of hydrothermal sites in Central Nepal -- 8.3.5. Overview of hydrothermal sites in Eastern Nepal -- 8.3.6. Overview of hydrothermal sites in the MFT zone -- 8.4.Conclusion -- 8.5.References -- Conclusion -- Rodolphe CATTIN and Jean-Luc EPARD of Authors -- Index -- Summaries of other volumes -- EULA. 330 8 $aThe Himalaya is well known as the largest and highest mountain belt on Earth. Advances in geoscience over the past few decades have revealed a complex picture of the dynamics of this giant, opening up questions about the initial stages of Himalayan building, lateral variations in its structures, variations in tectonic forcing, tectonic-climate coupling and assessments of the natural hazards affecting this area. In this three-volume book, we present the current knowledge on the building and present-day behavior of the Himalayan range. The objective is not to be exhaustive, but to provide some key elements used by researchers to unravel the many processes acting in the Himalayan dynamics. Mountain environments are at the forefront of climate change with glacier retreat, landslides, flash floods and water availability. Understanding the delicate balance that controls the dynamics of the Himalayan giant is now, more than ever, a major challenge for the scientific community. 607 $aHimalaya Mountains Region$xDescription and travel 610 $aGeophysics 610 $aGeology 610 $aScience 676 $a915.49604 702 $aCattin$b Rodolphe 702 $aEpard$b Jean-Luc 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910735567003321 996 $aHimalaya, dynamics of a giant 1$93421855 997 $aUNINA