Abstract
A methodology to evaluate the undrained cyclic resistance of sandy deposits from cone penetration tests through the state parameter is applied to the case history of the village of San Carlo (Italy), where widespread liquefaction phenomena occurred during the 2012 Emilia earthquake. The mechanical behaviour of the sand retrieved in the area of San Carlo was characterised within the framework of critical state soil mechanics via a series of monotonic and cyclic triaxial tests carried out on both undisturbed and reconstituted samples. Centrifuge cone penetration tests were also performed on reconstituted models of the same material. The results of centrifuge and undrained cyclic triaxial tests were interpreted through the state parameter to calibrate a direct correlation between the cone resistance, qc and the undrained cyclic resistance ratio (CRR). CRR profiles were deduced from the CPTs performed at sites in San Carlo where liquefaction took place using the correlation calibrated herein and a liquefaction assessment was carried out. The results of the proposed method was compared to a well-known simplified approach.
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References
Baldi G, Bellotti R, Ghionna V, Jamiolkowski M, Pasqualini E (1982) Design parameters for sand from CPT. In: Proceedings of 2nd ESOPT, Amsterdam, the Netherlands
Baldi G, Bellotti R, Ghionna V Jamiolkowski M, Pasqualini E (1986) Interpretation of CPT’s and CPTU’s 2nd par: drained penetration of sands. In: Proceedings of the 4th international geotechnical seminar. Nanyang Technological Institute, Singapore, pp 143–156
Baldi G, Belloni G, Maggioni W (1988) The ISMES Geotechnical Centrifuge. In: Corté JF (ed) Centrifuge 88, Paris. Balkema, Rotterdam, pp 45–48
Been K, Jefferies MG (1985) A state parameter for sands. Géotechnique 35(2):99–112
Been K, Crooks JHA, Becker DE, Jefferies MG (1986) The cone penetration test in sands: part I, state parameter interpretation. Géotechnique 36(2):239–249
Bellotti R, Bizzi G, Ghionna V (1982) Design, construction and use of a calibration chamber. In: Proceedings of the ESOPT 11, Amsterdam, vol 2, pp 439–446
Bigi G, Bonardi G, Catalano R, Cosentino D, Lentini F, Parotto M, Sartori RSP, Scandone P (1992) Structural model of Italy 1:500,000, CNR-GNDT, Geodinamic Project
Bolton MD, Gui MW, Garnier J, Corte JF, Bagge G, Laue J, Renzi R (1999) Centrifuge cone penetration tests in sand. Geotechnique 49(4):543–552
Caillemer BM (1975) An experimental study in the U.F. static cone calibration chamber, M.Sc. Thesis, Univ. of Florida, Gainesville
Calabrese L, Martelli L, Severi P (2012) Stratigrafia dell’area interessata dai fenomeni di liquefazione durante il terremoto dell’Emilia (Maggio 2012). In: Proceedings of the 31st GNGTS, November 20–22, Potenza, pp 119–125
Carter JP, Yeung SK (1985) Analysis of cylindrical cavity expansion in a strain weakening material. Comput Geotech 1:161–180
Carter JP, Booker JR, Yeung SK (1986) Cavity expansion in cohesive frictional soils. Géotechnique 36(3):349–358
Cetin KO, Seed RB, Kiureghian DA, Tokimastu K, Harder LF, Kayen RE, Moss RES (2004) Standard penetration test-based probabilistic and deterministic assessment of seismic soil liquefaction potential. J Geotech Geoenviron Eng 130(12):1314–1340
Fioravante V, Giretti D (2016) Unidirectional cyclic resistance of Ticino and Toyoura sands from centrifuge cone penetration tests. Acta Geotechnica 11(4):953–968. doi:10.1007/s11440-015-0419-3
Fioravante V, Jamiolkowski M, Tanizawa F, Tatsuoka F (1991) Calibration chamber tests on Toyoura sand. In: Proceeding of the 1st international symposium on calibration chamber testing ISOCCT1 Potsdam New York USA, pp 135–146
Fioravante V, Giretti D, Abate G, Aversa S, Boldini D, Capilleri PP, Cavallaro A, Chamlagain D, Crespellani T, Dezi F, Facciorusso J, Ghinelli A, Grasso S, Lanzo G, Madiai C, Massimino MR, Maugeri M, Pagliaroli A, Rainieri C, Tropeano G, Santucci De Magistris F, Sica S, Silvestri F, Vannucchi G (2013) Earthquake geotechnical engineering aspects of the 2012 Emilia-Romagna earthquake (Italy). In: 7th International conference on case histories in geotechnical engineering, April 29–May 4, 2013, Chicago
Galli P, Melloni F (1993) Nuovo catalogo nazionale dei processi di liquefazione avvenuti in occasione dei terremoti storici in Italia. Il Quaternario 6(2):271–292
Ghionna V, Jamiolkowski MB (1991) A critical appraisal of calibration chamber testing of sands. In: Proceedings of the first international symposium on calibration chamber testing, Potsdam, NY, USA
Giretti D, Fioravante V, Martelli L (2012) Centrifuge tests to evaluate the Po river bank seismic response. In: Proceedings of the 4th international conference on geotechnical and geophysical site characterization (ISC’4), September 15–18, 2012—Porto de Galinhas, Pernambuco, Brazil, pp 1179–1187
Holden JC (1971) Research on performance of soil penetrometers. Country Roads Board of Victoria Internal Report CE-SK-7l-l
Houlsby GT, Hitchman RC (1988) Calibration tests of cone penetrometers in sand. Géotechnique 8(1):39–44
Idriss IM (1999) An update to the Seed-Idriss simplified procedure for evaluating liquefaction potential. Proc, Workshop New Approaches to Liquefaction Analysis, Federal Highway Administration, Washington, DC
Idriss IM, Boulanger RW (2008) Soil liquefaction during earthquakes. Earthquake Engineering Research Institute. MNO-12
Ishihara K, Iwamoto S, Yasuda S, Takatsu H (1977) Liquefaction of anisotropically consolidated sand. In: Proceedings 9th international conference on soil mechanics and foundation engineering, Japanese Society of Soil Mechanics and Foundation Engineering, Tokyo, Japan, vol 2, pp 261–264
Ishihara K, Yamazaki A, Haga K (1985) Liquefaction of K0 consolidated sand under cyclic rotation of principal stress direction with lateral constraint. Soils Found 5(4):63–74
Jaky J (1944) The coefficient of earth pressure at rest. J Soc Hung Archit Eng 78:355–358
Jefferies M, Been K (2006) Soil liquefaction. A critical state approach. Taylor and Francis, London
Juang CH, Jiang T, Andrus RD (2002) Assessing probability based methods for liquefaction potential evaluation. J Geotech Geoenviron Eng 128(7):580–589
Juang CH, Fang SY, Khor EH (2006) First-order reliability method for probabilistic liquefaction triggering analysis using CPT. J Geotech Geoenviron Eng 132(3):337–350
Lavecchia G, de Nardis R, Cirillo D, Brozzetti F, Boncio P (2012) The May–June 2012 Ferrara Arc earthquakes (northern Italy): structural control of the spatial evolution of the seismic sequence and of the surface pattern of coseismic fractures. Ann Geophys 55(4):533–540
Li XS, Wang ZL (1998) Linear representation of steady state line for sand. J Geotech Geoenviron Eng ASCE 124(12):1215–1217
Moss RES (2003) CPT-based probabilistic assessment of seismic soil liquefaction initiation. Ph.D. dissertation, Univ. of California, Berkeley, CA
Moss RES, Seed RB, Kayen RE, Stewart JP, Der Kiureghian A, Cetin KO (2006) CPT-based probabilistic and deterministic assessment of in situ seismic soil liquefaction potential. J Geotech Geoenviron Eng ASCE 132(8):1032–1051
Reese JD (1975) An experimental study on the effects of saturation on the qc and fs values from cone penetration tests in the U.F. Calibration Chamber. M.Sc. Thesis, Univ. of Florida, Gainesville
RER and ENI-Agip (1998) Riserve idriche sotterranee della Regione Emilia-Romagna
Robertson PK, Wride CE (1998) Evaluating cyclic liquefaction potential using the cone penetration test. Can Geotech J 35(3):442–459
Salgado R, Mitchell J, Jamiolkowski M (1997) Cavity expansion and penetration resistance in sand. J Geotech Geoenviron Eng 123(4):344–354
Schmertmann JH (1978) Guidelines for cone penetration test, performance and design, report FHWA-TS-787-209, Federal Highway Administration, Washington, July 1978
Seed HB, Idriss IM (1971) Simplified procedure for evaluating soil liquefaction potential. J Soil Mech Found Div 97(9):1249–1273
Seed HB, Tokimatsu K, Harder LF, Chung RM (1985) The influence of SPT procedures in soil liquefaction resistance evaluations. J Geotech Eng 111(12):1425–1445
Toscani G, Burrato P, Di Bucci D, Seno S, Valensise G (2009) Plio-Quaternary tectonic evolution of the northern Apennines thrust fronts (Bologna-Ferrara section, Italy): seismotectonic implications. B Soc Geol Ital (Italian Journal of Geosciences) 128:605–613. doi:10.3301/IJG.2009.128.2.605
Acknowledgements
The Authors gratefully acknowledge the Seismic Surveys of the Emilia-Romagna Regions for having provided the results of in situ tests and the ISMGEO staff (particularly Mr. Sergio Airoldi and Dr. Andrea Saccenti) for having carried out centrifuge and laboratory tests.
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Giretti, D., Fioravante, V. A correlation to evaluate cyclic resistance from CPT applied to a case history. Bull Earthquake Eng 15, 1965–1989 (2017). https://doi.org/10.1007/s10518-016-0057-7
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DOI: https://doi.org/10.1007/s10518-016-0057-7