Abstract
Nowadays, the dynamic properties of soil and study of its dynamic response in connection with the designing of the structures resistant against earthquake seems more critical day by day along with the increase of the structures’ height and specialization of the civil operations. Since geophysical tests are often costly and time consuming, applying other tests results for estimation of Shear wave velocity is extremely useful. For this purpose, this paper focuses on determining and offering a relationship between the results of standard penetration test (SPT), which is highly quick, cost-effective, and common test, with shear wave velocity of soil. For this end, several boreholes with different depths were drilled in several coastal cities of the Caspian Sea, and SPT was carried out in them. Then downhole test for calculating shear wave velocity profile was performed in all the studied sites using the same borehole and, in some cases, by drilling a new borehole. After that, the data were analyzed for determining the correlation via a suitable statistical method. The results indicated that the obtained relationship is suitably compatible with the universal practical relationships presented for sandy soils and stands approximately in the upper limit of the relationships. It is noteworthy that although applying these relationships for the estimation of shear wave velocity in the coastal sands of the Caspian Sea for small projects and the initial phases of the average and big projects is recommended, it must be considered that direct geophysical methods must be employed in cases where this parameter seems more critical.
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References
Abrahamson N, Silva W (2008) Summary of the Abrahamson & Silva NGA ground-motion relations. Earthquake Spectra 24(1):67–97
Athanasopoulos GA (1995). “Empirical correlations Vs-NSPT for soils of Greece: a comparative study of reliability,” Proc. 7th Int. Conf. on Soil Dynamics and Earthquake Engineering (Chania, Crete) ed A S Cakmak (Southampton: Computational Mechanics), 19–36
Boore DM, Atkinson GM (2008) Ground-motion prediction equations for the average horizontal component of PGA, PGV, and 5 %-damped PSA at spectral periods between 0.01 s and 10.0 s. Earthquake Spectra 24(1):99–138
Choi Y, Stewart JP (2005) Nonlinear site amplification as function of 30 m shear wave velocity. Earthquake Spectra 21(1):1–30
Dikmen U (2009). “Statistical correlations of shear wave velocity and penetration resistance for soils,” Journal of Geophysics and Engineering 6:61–72
Fujiwara T (1972). “Estimation of ground movements in actual destructive earthquakes,” Proc. 4th European Symp. Earthquake Engineering (London), 125–32
Hasancebi N, Ulusay R (2006). “Empirical correlations between shear wave velocity and penetration resistance for ground shaking assessments,” Bull Eng Geol Environ 66:203–213
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
Imai T, Tonouchi K (1982). “Correlation of N-value with S-wave velocity and shear modulus,” Proc. 2nd European Symp. Of Penetration Testing (Amsterdam), 57–72
Imai T, Yoshimura M (1975) The relation of mechanical properties of soils to P- and S-wave velocities for soil ground in Japan. Oyo Tech Note. TN-07 Sept. 1975
Iyisan R (1996) Correlations between shear wave velocity and in-situ penetration test results. Tech J Chamb Civ Eng Turk 7:1187–1199 (in Turkish)
Jafari MK, Asghari A, Rahmani I (1997). “Empirical correlation between shear wave velocity (Vs) and SPT-N value for south of Tehran soils,” Proc. 4th Int. Conf. on Civil Engineering (Tehran, Iran) (in Persian)
Jinan Z (1987). “Correlation between seismic wave velocity and the number of blow of SPT and depth,” Chin J Geotech Eng (ASCE), 92–100
Kanai K (1966). “Conf. on Cone Penetrometer The Ministry of Public Works and Settlement (Ankara, Turkey),” (presented by Y Sakai 1968)
Kiku H, Yoshida N, Yasuda S, Irisawa T, Nakazawa H, Shimizu Y, Ansal A, Erkan A (2001). “In-situ penetration tests and soil profiling in Adapazari, Turkey,” Proc. ICSMGE/TC4 Satellite Conf. on Lessons Learned from Recent Strong Earthquakes, 259–65
Lee SH (1990) Regression models of shear wave velocities. J Chin Inst Eng 13:519–532
Lee H, Hsien S (1992) ANALYSIS of the multicollinearity of regression equations of shear wave velocities, Soils and Foundations. Jpn Soc Soil Mech Found Eng 32(1):205–214
Ohba S, Toriuma I (1970). “Dynamic response characteristics of Osaka Plain,” Proc. Ann. Meeting AIJ (in Japanese)
Ohsaki Y, Iwasaki R (1973) On dynamic shear modula and Poisson ratio of soil deposits. Soil and Found 13(4):61–73
Ohta Y, Goto N (1978) Empirical shear wave velocity equations in term of characteristic soil indexes. Earthq Eng Struct Dyn 6:167–187
Ohta T, Hara A, Niwa M, Sakano T (1972). “Elastic shear moduli as estimated from N-value,” Proc. 7th Ann. Convention of Japan Society of Soil Mechanics and Foundation Engineering, 265–8
Okamoto T, Kokusho T, Yoshida Y, Kusuonoki K (1989). “Comparison of surface versus subsurface wave source for P–S logging in sand layer,” Proc. 44th Ann. Conf. JSCE, 3:996–7 (in Japanese)
Pitilakis K, Raptakis D, Lontzetidis KT, Vassilikou T, Jongmans D (1999). “Geotechnical and geophysical description of Euro-Seistests, using field and laboratory tests, and moderate strong ground motions,” J Earthq Eng 3:381–409
Seed HB, Idriss IM (1981). Evaluation of liquefaction potential sand deposits based on observation of performance in previous earthquakes. ASCE National Convention (MO), 81–544
Shibata T (1970). “Analysis of liquefaction of saturated sand during cyclic loading,” Disaster Prevention Res. Inst Bull 13:563–70
Sisman H (1995). “The relation between seismic wave velocities and SPT, pressuremeter tests,” MSc Thesis, Ankara University (in Turkish)
Sykora DW, Koester PJ (1988) Correlations between dynamic shear resistance and standard penetration resistance in soils. Earthq Eng Soil Dyn 2:389–404
Sykora DW, Stokoe KHI (1983) Correlations of in situ measurements in sands with shear velocity. Geotechnical Engineering Report, GR83-33. The University of Texas at Austain, Austain Tex
Sykora DE, Stokoe KH (1983b) Correlations of in-situ measurements in sands of shear wave velocity. Soil Dyn Earthq Eng 20:125–136
Ulugergerli UE, Uyanik O (2007) Statistical correlations between seismic wave velocities and SPT blow counts and the relative density of soils. J Test Eval 35:1–5
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Esfehanizadeh, M., Nabizadeh, F. & Yazarloo, R. Correlation between standard penetration (N SPT) and shear wave velocity (V S) for young coastal sands of the Caspian Sea. Arab J Geosci 8, 7333–7341 (2015). https://doi.org/10.1007/s12517-014-1751-x
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DOI: https://doi.org/10.1007/s12517-014-1751-x