Abstract
Subsurface lithology and seismic site classification of Lucknow urban center located in the central part of the Indo-Gangetic Basin (IGB) are presented based on detailed shallow subsurface investigations and borehole analysis. These are done by carrying out 47 seismic surface wave tests using multichannel analysis of surface waves (MASW) and 23 boreholes drilled up to 30 m with standard penetration test (SPT) N values. Subsurface lithology profiles drawn from the drilled boreholes show low- to medium-compressibility clay and silty to poorly graded sand available till depth of 30 m. In addition, deeper boreholes (depth >150 m) were collected from the Lucknow Jal Nigam (Water Corporation), Government of Uttar Pradesh to understand deeper subsoil stratification. Deeper boreholes in this paper refer to those with depth over 150 m. These reports show the presence of clay mix with sand and Kankar at some locations till a depth of 150 m, followed by layers of sand, clay, and Kankar up to 400 m. Based on the available details, shallow and deeper cross-sections through Lucknow are presented. Shear wave velocity (SWV) and N-SPT values were measured for the study area using MASW and SPT testing. Measured SWV and N-SPT values for the same locations were found to be comparable. These values were used to estimate 30 m average values of N-SPT (N 30) and SWV (V 30s ) for seismic site classification of the study area as per the National Earthquake Hazards Reduction Program (NEHRP) soil classification system. Based on the NEHRP classification, the entire study area is classified into site class C and D based on V 30s and site class D and E based on N 30. The issue of larger amplification during future seismic events is highlighted for a major part of the study area which comes under site class D and E. Also, the mismatch of site classes based on N 30 and V 30s raises the question of the suitability of the NEHRP classification system for the study region. Further, 17 sets of SPT and SWV data are used to develop a correlation between N-SPT and SWV. This represents a first attempt of seismic site classification and correlation between N-SPT and SWV in the Indo-Gangetic Basin.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aki, K., P. G. Richards, (1980), Quantitative seismology, W. H. freeman and Co.
Ambraseys, N., and R. Bilham, (2003), Revaluated intensities for the Great Assam Earthquake of 12 June 1897, Shillong India, Bull. Seism. Soc. Am. 93(2), 655–673.
Anbazhagan P, Sitharam, TG, and Vipin K. S. (2009), Site classification and estimation of surface level seismic hazard using geophysical data and probabilistic approach, J. Appl. Geophys. 68(2), 219–230.
Anbazhagan P., and Sitharam T. G. (2009), Spatial Variability of the Weathered and Engineering Bed rock using Multichannel Analysis of Surface Wave Survey, Pure Appl. Geophys. 166(3), 409–428.
Anbazhagan, P. and Sitharam, T. G. (2010), Relationship between Low Strain Shear Modulus and Standard Penetration Test ‘N’ Values, ASTM Geotech. Test. Jour. 33(2), 150–164.
Anbazhagan, P., and Sitharam, T. G. (2008a), Mapping of Average Shear Wave Velocity for Bangalore Region: A Case Study, Journ. Environ. Eng. Geophy. 13(2), 69–84.
Anbazhagan P. and Sitharam, T. G. (2008b), Site Characterization and Site Response Studies Using Shear Wave Velocity, Journ. Seism. Earthq. Eng. 10(2), 53–67.
Anbazhagan, P., Thingbaijam K. K. S., Nath, S. K., Narendara Kumar, J.N. and Sitharam, T.G. (2010), Multi-criteria seismic hazard evaluation for Bangalore city, India, J. Asian Earth Sci. 38, 186–198.
Anbazhagan, P., P. Adithya and H. N. Rashmi (2011), Amplification Based on Shear Wave Velocity for Seismic zonation: Comparison of Empirical Relations and Site Response Results for Shallow Engineering Bedrock Sites, Geomechanics and Engineering, An International Journal, 3(3), 189–206.
AnbazhaganP, AdityaParihar, H.N.Rashmi (2012), Review of correlations between SPT N and shear modulus: A new correlation applicable to any region. Soil Dynamics and Earthquake Engineering, published in on line, doi:10.1016/j.soildyn.2012.01.005.
Athanasopoulos G. A. (1995), Empirical correlation Vs-N SPT for soils of Greece; a comparative study of reliability study of reliability, Proceedings of the 7th Int. Conf. on Soil Dynamics Earthquake Engineering (Chania, Crete) A S Cakmak (Southampton: Computation Mechanics). 19–36.
Bendick, R., Bilham, R., Fielding, S. E., Gaur, V., Hough, S. E., Kier, G., Kulkarni, M. N., Martin, S., Muller, K and Mukul, M. (2001), The January 26, 2001 “Republic Day” Earthquake, India, Seismol. Res. Lett. 72(3), 328–335.
Boore, D. M. (2004), Estimating Vs (30) (or NEHRP Site Classes) from Shallow Velocity Models (Depth < 30 m), Bull. Seismol. Soc. Am. 94(2), 591–597.
Borcherdt, R. D. (1994), Estimates of site-dependent response spectra for design (methodology and justification), Earthquake Spectra. 10, 617–653.
BSSC (2003), “NEHRP recommended provision for seismic regulation for new buildings and other structures (FEMA 450), Part 1: Provisions,” Building Safety seismic council for the federal Emergency Management Agency, Washington D. C.
Dikmen, U., (2009), Statistical Correlations of shear wave velocity and penetration resistance for soils, J. Geophys. Eng. 6, 61–72.
District Resource Map (DRM) (2001), Lucknow, Uttar Pradesh, Geological Survey of India (GSI), Northern Region.
Dorman, J., M. Ewing, (1962), Numerical inversion of seismic surface wave dispersion data and crust-mantle structure data in the New York-Pennsylvania area, J. Geophys. Res. 67, 5227–5241.
Farrar, J.A., Nickell, J., Alien, M.G., Goble, G. and Berger, J. (1998), Energy loss in long rod penetration testing — Terminus Dam liquefaction investigation, Proceedings of the ASCE Specialty Conf. on Geotechnical Earthquake Engineering and Soil Dynamics III, Seattle. 75, 554–567.
Fujiwara, T. (1972), Estimation of ground movement in actual destructive earthquakes, Proceedings of the Fourth European Symposium on Earthquake Engineering (London), 125–132.
Hanumantharao C. and G. V. Ramana (2008), Dynamic Soil properties for microzonation of Delhi, India, J. Earth. Syst. Sci. 117(S2), 719–730.
Hasancebi N and R. Ulusay, (2007), Empirical correlation between shear wave velocity and penetration resistance for ground shaking assessment, Bull. Eng. Geol. Environ. 66, 203–213.
IBC (2009). International Building Code, published by International Codes Council.
Imai T and K. Tonouchi (1982), Correlation of N value with S wave velocity and shear modulus, Proceedings of the 2nd Eurpean Symposium of Penetration Testing (Amsterdam). 57–72.
Imai T, Fumoto H and K. Yokota, (1975), The relation of mechanical properties of soil to P and S wave velocities in Japan, Proceedings of the 4th Japan Earthquake Engineering Symposium (in Japanese). 89–96.
Imai, T. and Yoshimura, Y. (1975), The relation of mechanical properties of soils to P and S wave velocities for ground in Japan, Technical note OYO Corporation.
Imai T., (1977), P and S wave velocities of the ground in Japan, Proc. 9th Int. Conf. on Soil Mechanics and Foundation Engineering. 2, 127–32.
IS 1498 (1970), Indian Standard Classification and identification of soils for general engineering purposes, First revision, Bureau of Indian Standards, New Delhi.
IS 1892 (1974), Indian Standard code of Practice for subsurface investigation for foundations, Bureau of Indian Standards, New Delhi.
IS 2131 (1981), Indian Standard, Method for standard penetration test for soils, First revision, Bureau of Indian Standards, New Delhi.
IS 2132 (1986), Indian Standard code of Practice for thin walled tube sampling of soils, Second revision, Bureau of Indian Standards, New Delhi.
IS 1893 (2002), Indian Standard Criteria for Earthquake Resistant Design of Structures, Part 1 - General Provisions and Buildings, Bureau of Indian Standards, New Delhi.
Iyisan R. (1996), Correlation between Shear wave velocity and in situ penetration test results, Tech. Journ. Chamber Civil Eng. Turkey (in Turkish). 7, 1187–99.
Jafari M. K., A. Asghari and I. Rahmani (1997), Empirical correlation between shear wave velocity and SPT-N values for south of Tehran soils, Proceedings of the 4th Int. Conf. on Civil Engineering, (Tehran, Iran) (in Persian).
JRA (Japan Road Association, 1980), Specification for Highway bridges. Part V, Earthquake Resistant design.
Khan, K. (1874), Muntakhab-ul-Lubab, M. H., Bibl. India series, Calcutta.
Khattri K. N. (1987), Great Earthquakes, seismicity gaps and potential of earthquake disaster along the Himalayan plate boundary, Tectonophysics, 138(1), 79–92.
Koçkar, M. K., Akgün, H., and Rathje, E. M. (2010), Evaluation of site conditions for the Ankara Basin of Turkey based on seismic site characterization of near-surface geologic materials, Soil Dynam. Earthquake Eng. 30(1), 8–20.
Kovacs, W.D., L. A. Salomone and F. Y. Yokel (1981), Energy Measurement in the Standard Penetration Test, U.S. Department of Commerce and National, Bureau of Standards, Washington D.C.
Mahajan, A. K. and Virdi, K. S. (2001), Macroseismic field generated by 29 March, 1999 Chamoli Earthquake and its seismotectonics, J. Asian Earth Sci. 19(4), 507–516.
Mahajan, A. K., R. J. Sporry, P. K. Champati Ray, R. Ranjan R, S. Slob and W. S. Van (2007), Methodology for site-response studies using multi-channel analysis of surface wave technique in Dehradun city, Curr. Sci. 92(7), 945–955.
Mari, J. L., (1984), Estimation of static correction for shear wave profiling using the dispersion properties of Love waves, Geophysics. 49, 1169–1179.
Mark, A.R. and J. D. Bray, N. A. Abrahamson (2001), An Empirical Geotechnical Seismic Site Response Procedure, Earthquake Spectra. 17(1), 65–87.
Nadeshda, TNN, “Lucknow is on Earthquake List” Published online, Times of India. (2004), http://timesofindia.indiatimes.com/city/lucknow/Lucknow-is-on-earthquake-list/articleshow/679471.cms (Last accessed on 11/1/2011).
Nihon (2011), Liquefaction induced damages caused by the M 9.0 East Japan mega earthquake on March 11, 2011, Tokyo Metropolitan University, Hisataka Tano, Nihon University, Koriyama Japan, with cooperation of save Earth co. and Waseda University.
Ohba, S., and Tourima, I. (1970), Dynamic response characteristics of Osaka plain, Proceedings of Annual Meeting, AIJ (in Japanese).
Ohsaki, Y. and R. Iwasaki (1973), Dynamic shear moduli and Poisson’s ratio of soil deposits, Soils and Foundation. 13, 61–73.
Ohta, Y. and N. Goto (1978), Empirical shear wave velocity equations in terms of characteristic soil indexes, Earthquake Eng. Struct. Dynam. 6(2), 167–87.
Oldham, T. (1883), A catalogue of Indian earthquakes, Mem Geol. Surv. India, Geol. Surv. India. 19, 163–215.
Park, C.B., Miller, R.D., Xia, J., 1999. Multi-channel analysis of surface waves, Geophysics 64(3), 800–808.
PCRSMJUA “Project Completion Report of Seismic Microzonation of Jabalpur Urban Area”. (2005), published by Department of Science and Technology, Government of India.
Pitilakis, K. (2004), Site Effects in Recent Advances in Earthquake Geotechnical Engineering and Microzonation, Ed Ansal, A. Kluwer Academic Publications, Netherlands, 368, 139–197.
Press, W. H., S. A. Teukosky, W. T. Vettering and B. P. Flannery, (1992), Numerical recipes in C: Cambridge Univ. Press.
Raghukanth, S. T. G. and R. N. Iyengar (2007), Estimation of seismic spectral acceleration in Peninsular India, Journ. Earth Syst. Sci. 116(3), 199–214.
Rajendran, C. P., K. Rajendran, K. H. Voha and A. S. Gaur (2003), The odds of seismic source near Dwarka, NW Gujarat: An evaluation based on Proxies, Curr. Sci. 84, 695–701.
Rao, K. S. and Neelima, S. D. (2007), Liquefaction studies for seismic microzonation of Delhi region, Curr. Sci. 92(5), 646–654.
Sastri, V. V., Bhandari, L. L., Raju, A. T. R. and Datta, A. K. (1971), Tectonic framework and subsurface stratigraphy of the Ganga basin, J. Geol. Soc. India. 12(3), 222–233.
Schmertmann, J. H. and A. V. Palacios, (1979), Energy dynamics of SPT, J. Geotech. Eng. Div. 105 (8), 909–926.
Schwab, F. A. and L. Knopoff, (1972), Fast surface wave and free mode computation, In: Bolt, B. A. (Ed.), Methods in Computational Physics, Academic press, 87–180.
Seed, H. B., Idriss I. M. and Arango I. (1981), Evaluation of liquefaction potential using field performance data, Journ. Geo. Eng., ASCE. 109, 458–482.
Sivrikaya, O. and Togrol, E. (2006), Determination of undrained strength of fine grained soils by means of SPT and its application in Turkey, Eng Geol. 86(1), 52–69.
SURFSEIS© Software for Multichannel Analysis of Surface 1006 Waves, Kansas Geological Survey, http://www.kgs.ku.edu/1007software/surfseis/index.html, last visited on 12/12/2011.
Uma Maheshwari, R., Boominathan, A. and Dodagoudar, G. R. (2010), Use of surface waves in statistical correlations of shear wave velocity and Penetration Resistance of Chennai soils, Geotech Geol Eng, 28, 119–137.
Vipin K. S., Anbazhagan P., Sitharam T. G. (2009), Estimation of peak ground acceleration and spectral acceleration for South India with local site effects: probabilistic approach, Nat. Hazards Earth Syst. Sci. 9, 865–878.
Xia, J., Miller, R.D., Park, C.B., 1999. Estimation of near-surface shear-wave velocity by inversion of Rayleigh wave, Geophysics 64(3), 691–700.
Acknowledgments
The authors would like to thank the Ministry of Earth Science (MoES) for the funding project “Site Characterization of Lucknow urban centre with studies of Site Response and Liquefaction Hazard” ref. no. MoES/P.O.(Seismo)/23(656)/SU/2007. Thanks are also due to Jal Nigam, Government of Uttar Pradesh, India for providing necessary borehole data across Lucknow, which was found to be very useful in understanding the subsurface geology of Lucknow. Thanks go to Aditya Parihar and Naveen James for their help in conducting field studies.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Anbazhagan, P., Kumar, A. & Sitharam, T.G. Seismic Site Classification and Correlation between Standard Penetration Test N Value and Shear Wave Velocity for Lucknow City in Indo-Gangetic Basin. Pure Appl. Geophys. 170, 299–318 (2013). https://doi.org/10.1007/s00024-012-0525-1
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00024-012-0525-1