Abstract
A 3-D structural model for the Kachchh rift zone has been constructed based on the results from our earlier studies using S-to-P converted phase, and joint inversion of P-receiver functions and surface wave dispersion data, which reveals a a seismogenic crustal volume (∼ 50×50×45 km3) with large sediment thickness and marked crustal as well as asthenospheric thinning below the Kachchh rift zone (KRZ). A local earthquake velocity tomography using 24019 P- as well as 23825 S-wave arrival times of 3750 relocated events from 41 three- component seismographs has been performed. Vp and Vs tomograms detect a distinct very high velocity lower crustal anomaly (Vp: 6.8-7.8 km/s; Vs: 3.9-4.3 km/s; Vp/Vs:1.7-1.8) at deeper depths (≥ 20 km) below the central KRZ. Three high velocity anomalies at 5-30 km depths have also been mapped below the Wagad uplift, Kachchh rift and Banni regions. These high velocity anomalies are interpreted as mafic plutons, within the mapped crustal volume, which might have resulted from the 65 Ma Deccan plume episode. Relocations of most of M≥5 events (including 2001 Bhuj mainshock) fall either near the contacts between high and low velocity zones or in the high-velocity zones while some earthquakes (including the 1956 Anjar earthquake) also occurred in the low-velocity zones (8-18% drop in Vs, indicating the presence of fluids). We propose that mapping of such a scenario of crustal and lithospheric structure where resultant tectonic forces encourage seismicity is crucial for the assessment of the intraplate seismic hazard.
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References
Benz, H.M., Chouet, B.A., Dawson, P.B., Lahr, J.C., Page, R.A. and Hole, J.A. (1996) Three-dimensional P and S wave velocity structure of Redoubt Volcano, Alaska. Jour. Geophys. Res., v.101, pp.8111–8128.
Biswas, S.K. (2005) A review of structure and tectonics of Kutch basin, western India, with special reference to earthquakes. Curr. Sci., v.88, pp.1592–1600.
Chopra, S., Rao, K.M. and Rastogi, B.K. (2010) Estimation of sedimentary thickness in Kachchh basin, Gujarat using SP converted phase. Pure Appl. Geophys., v.167, pp.1247–1257.
Copley, A., Jean Philippe Avouac, J-P., Hollingsworth, J. and Leprince, S. (2011) The 2001 Mw 7.6 Bhuj earthquake, low fault friction, and the crustal support of plate driving forces in India. Jour. Geophys. Res., v.116, B08405, doi:https://doi.org/10.1029/2010JB008137.
Courtillot, V., Besse, J., Vandamme, D., Montigny, R., Jaeger, J.J., and Cappetta, H. (1986) Deccan flood basalts at the Cretaceous/Tertiary boundary? Ear. Planet. Sci. Lett., v.80, pp. 361–374.
Gupta, H.K., Purnachandra Rao, N., Rastogi, B.K. and Sarkar, D. (2001) The Deadliest Intraplate Earthquake. Science, v.291, pp.2101–2102.
Kaila, K.L., Tewari, H.C., Sarma, P.L.N. (1981) Crustal structure from deep seismic sounding studies along Navibandar-Amreli profile in Saurashtra, India. Deccan Volcanism and Related Basalt Provinces in Other Parts of the World. Mem. Geol. Soc. India, v.3, pp.218–232.
Kandregula, R. S., Kothyari, G. C., Swamy, K.V., Taloor, A.K., Lakhote, A., Thakkar, M.G., Pathak, V., Malik, K. (2021) Estimation of regional surface deformation post the 2001 Bhuj earthquake in the Kachchh region, western India, using RADAR interferometry. GeoCarto International, DOI: https://doi.org/10.1080/10106049.2021.1899299.
Khan, P.K., Mohanty, S.P., Sinha, S. and Singh, D. (2016) Occurrences of large-magnitude earthquakes in the Kachchh region, Gujarat, western India: Tectonic implications. Tectonophysics, v.679, pp.102–116.
Kissling, E. (1995) Velest Users Guide, Internal report, Institute of Geophysics, ETH Zurich, pp.26.
Lakhote, A., Thakkar, M.G., Kandregula, R.S., Chirag, J., Kothyari, G. C., Chauhan, G., Bhandari, S. (2021) Estimation of active surface deformation in the eastern Kachchh region, western India: Application of multi-sensor DinSAR technique. Quaternary Internat., v.575/576, pp.130–140.
Mandal, P., Rastogi, B.K., Satyanarayana, H.V.S., Kousalya, M., Vijayraghavan, R., Satyamurthy, C., Raju, I.P., Sarma, A.N.S. and Kumar, N. (2004) Characterization of the causative fault system for the 2001 Bhuj earthquake of Mw 7.7. Tectonophysics, v.378, pp.105–121.
Mandal, P. (2007) Sediment Thicknesses and Qs vs. Qp relations in the Kachchh rift basin, Gujarat, India using Sp converted phases. Pure Appl. Geophy., v.164, pp.135–160.
Mandal, P. and Pujol, J. (2006) Seismic imaging of the Aftershock zone of the 2001 Mw7.7 Bhuj earthquake, India. Geophys. Res. Lett., v.33, L05309, pp.1–4.
Mandal, P. and Pandey, O.P. (2011) Seismogenesis of the lower crustal intraplate earthquakes occurring in Kachchh, Gujarat, India. Journal of Asian Earthsciences, v.42, pp.479–491.
Mandal, P. (2019) A possible origin of intraplate earthquakes in the Kachchh rift zone, India, since the 2001 Mw7.7 Bhuj earthquake. Jou. of Asian Earth-sciences, v.170, pp.56–72.
Mandal, P., Chadha, R.K., Raju, I.P., Kumar, N., Satyamurty, C., Narsaiah, R. and Maji, A. (2007) Coulomb static stress variations in the Kachchh, Gujarat, India: Implications for the occurrences of two recent earthquakes (Mw5.6) in the 2001 Bhuj earthquake region. Geophysical Journal International, v.168(1), pp.281–285.
Mandal, P. (2020) Three-dimensional seismic velocity imaging of the Kachchh rift zone, Gujarat, India: Implications toward the crustal mafic pluton induced intraplate seismicity. Journal of Asian Earth Sciences, v.192, 104226, pp.1–7.
Pujol, J. (1988) Comments on the joint determination of hypocenters and station corrections. Bull. Seismol. Soc. Amer., v.78, pp.1179–1189.
Rastogi, B.K., Mandal, P. and Biswas, S. (2014) Seismogenesis of earthquakes occurring in the ancient rift basin of Kachchh, Western India. In the book on “Intraplate Earthquakes” edited by P. Talwani, Cambridge University Press, pp.126–161. https://doi.org/10.1017/CBO9781139628921.007.
Singh, B., Gupta, A.K. and Mandal, P. (2017) Sediment thickness and QS-QP relations in the Kachchh rift basin, India, using converted phases. Bull. Seism. Soc. Amer., v.107, pp.2532–2539.
Zhao, D. and Negishi, H. (1998) The 1995 Kobe earthquake: Seismic image of the source zone and its implications for the rupture nucleation. Geophys. Res. Lett., v.103(B5), pp.9967–9986.
Acknowledgements
Author is grateful to the Director, Council of Scientific and Industrial Research — National Geophysical Research Institute (CSIR-NGRI), Hyderabad, India, for his support and permission to publish this work. Author is also thankful to Prof. H. K. Gupta, former Director, CSIR-NGRI, Hyderabad, for his encouragement and fruitful scientific discussions. Figures were plotted using the Generic Mapping Tool (GMT) software (https://doi.org/10.1029/2019GC008515). All software and support data related to GMT software are freely accessible and available from this site (www.genericmappingtools.org). The elevation data used in generating GMT plots are obtained from the open source Digital Elevation Model (DEM) (https://asterweb.jpl.nasa.gov/gdem.asp).
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Mandal, P. Structure of the Seismically Active Kachchh Region. J Geol Soc India 97, 1163–1168 (2021). https://doi.org/10.1007/s12594-021-1846-4
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DOI: https://doi.org/10.1007/s12594-021-1846-4