Soil-liquefaction-induced damage has been a major cause of ground failure and led to structural damage in the past earthquake events. With recent shifts in civil engineering to performance-based design methods, the traditional factor-of-safety-based approach to avoid liquefaction initiation may not be economical to control liquefaction-induced deformations directly leading to damage. In this article, a novel approach using the magnetorheological effect of micron-sized magnetite particles in liquefied sand for post-liquefaction stabilization and deformation mitigation is proposed. The mixture of sand and micron-sized magnetite particles, termed as magnetorheological sand, illustrates field-dependent behavior similar to other magnetorheological materials. The magnetorheological effect is illustrated through a sinking cylinder test of saturated magnetorheological sand prepared with 90% F75 silica sand and 10% 30-micron magnetite particles by weight. The magnetic-field-dependent properties of magnetorheological sand are then fit to a numerical model for evaluation as a foundation material. The performance of a five-story structure resting on a layer of soil on rigid rock with soil–structure interaction is evaluated. The numerical simulation results demonstrate that magnetorheological sand is effective in mitigating liquefaction-induced deformation and has the potential to outperform alternative mitigation approaches.
AkaiKBrayJDChristianJTet al. (1997) Geotechnical Reconnaissance of the Effects of the January 17, 1995, Hyogoken-Nanbu Earthquake, Japan. Darby, PA: Diane Publishing.
2.
ASTM D4254 (2000) Standard test methods for minimum index density and unit weight of soils and calculation of relative density.
3.
BirdJFBommerJJ (2004) Earthquake losses due to ground failure. Engineering Geology75: 147–179.
4.
BoulangerRWHaydenRF (1995) Aspects of compaction grouting of liquefiable soil. Journal of Geotechnical Engineering121: 844–855.
5.
CarlsonJDJollyMR (2000) MR fluid, foam and elastomer devices. Mechatronics10: 555–569.
6.
ChopraISirohiJ (2013) Smart Structures Theory. New York: Cambridge University Press.
7.
CubrinovskiMIshiharaK (1999) Empirical correlation between SPT N-value and relative density for sandy soils. Soils and Foundations39: 61–71.
8.
De VicenteJKlingenbergDJHidalgo-AlvarezR (2011) Magnetorheological fluids: a review. Soft Matter7: 3701–3710.
9.
DobryRAbdounT (2015) Cyclic shear strain needed for liquefaction triggering and assessment of overburden pressure factor Kσ. Journal of Geotechnical and Geoenvironmental Engineering141: 04015047.
10.
HamadaM (2014) Soil liquefaction and countermeasures. In: HamadaM (ed.) Engineering for Earthquake Disaster Mitigation. Tokyo, Japan: Springer, pp. 125–152.
11.
HamadaMSatoHKawakamiT (1994) A consideration of the mechanism for liquefaction-related large ground displacement. In: Proceedings of the 5th US Japan workshop on earthquake resistant design of lifeline facilities and countermeasures for soil liquefaction, Salt Lake City, UT, 29 September–1 October.
12.
HanY (1997) Dynamic vertical response of piles in nonlinear soil. Journal of Geotechnical and Geoenvironmental Engineering123: 710–716.
13.
HardinBODrnevichVP (1972) Shear modulus and damping in soils: design equations and curves. Journal of the Soil Mechanics and Foundations Division98: 603–624.
14.
HuangYWenZ (2015) Recent developments of soil improvement methods for seismic liquefaction mitigation. Natural Hazards76: 1927–1938.
15.
IncecikMCeranI (1995) Cement grouting model tests. Bulteni-Istanbul Teknik Universitesi48: 305–318.
16.
IshiharaKKogaY (1981) Case studies of liquefaction in the 1964 Niigata earthquake. Soils and Foundations21: 35–52.
17.
KeivanAPhillipsBMIkenagaMet al. (2017) Causal realization of rate-independent linear damping for the protection of low-frequency structures. Journal of Engineering Mechanics143: 04017058.
18.
KellyJLeitmannGSoldatosA (1987) Robust control of base-isolated structures under earthquake excitation. Journal of Optimization Theory and Applications53: 159–180.
MeyerhofG (1956) Penetration tests and bearing capacity of cohesionless soils. Journal of the Soil Mechanics and Foundations Division82: 1–19.
21.
MitchellJK (2008) Mitigation of liquefaction potential of silty sands. In: From research to practice in geotechnical engineering conference, New Orleans, LA, 9–12 March, pp. 433–451. Reston, VA: American Society of Civil Engineers.
22.
NakanoMYamamotoMJollyM (1997) Dynamic viscoelasticity of a magnetorheological fluid in oscillatory slit flow. In: Proceedings of the 6th international conference on electro-rheological fluids, magneto-rheological suspensions and their applications, Yonezawa, Japan, 22–25 July.
23.
PavlenkoOIrikuraK (2002) Changes in shear moduli of liquefied and nonliquefied soils during the 1995 Kobe earthquake and its aftershocks at three vertical-array sites. Bulletin of the Seismological Society of America92: 1952–1969.
24.
PhillipsRW (1969) Engineering applications of fluids with a variable yield stress. PhD Thesis, University of California, Berkeley, CA.
25.
SawickiAMierczyńskiJ (2009) On the behaviour of liquefied soil. Computers and Geotechnics36: 531–536.
26.
SeedHBIdrissIM (1970) Soil moduli and damping factors for dynamic response analyses.
27.
SeedHBIdrissIM (1971) Simplified procedure for evaluating soil liquefaction potential. Journal of the Soil Mechanics and Foundations Division97: 1249–1273.
28.
SeedHBIdrissIM (1982) Ground Motions and Soil Liquefaction During Earthquakes. Berkeley, CA: Earthquake Engineering Research Institute.
29.
SeedRB (1990) Preliminary Report on the Principal Geotechnical Aspects of the October 17, 1989 Loma Prieta Earthquake. Berkeley, CA: Earthquake Engineering Research Center, University of California.
30.
SeedRBCetinKOMossREet al. (2003) Recent advances in soil liquefaction engineering: a unified and consistent framework. In: Proceedings of the 26th annual ASCE Los Angeles geotechnical Spring seminar, Long Beach, CA, 30 April.
31.
ShengcongFTatsuokaF (1984) Soil liquefaction during Haicheng and Tangshan earthquake in China: a review. Soils and Foundations24: 11–29.
32.
SumerBMFredsøeJ (2002) The Mechanics of Scour in the Marine Environment. Singapore: World Scientific.
33.
WeissKDCarlsonJDNixonDA (1994) Viscoelastic properties of magneto-and electro-rheological fluids. Journal of Intelligent Material Systems and Structures5: 772–775.
34.
WolfJP (1994) Foundation Vibration Analysis Using Simple Physical Models. Upper Saddle River, NJ: Pearson Education.
35.
YasudaSNagaseHKikuHet al. (1992) The mechanism and a simplified procedure for the analysis of permanent ground displacement due to liquefaction. Soils and Foundations32: 149–160.
36.
YasudaSTerauchiTMorimotoHet al. (1998) Post liquefaction behavior of several sands. In: Proceedings of the 11th European conference on earthquake engineering, Paris, 6–11 September, p. 222. Rotterdam: A.A. Balkema.
37.
YuanHYangSHAndrusRDet al. (2004) Liquefaction-induced ground failure: a study of the Chi-Chi earthquake cases. Engineering Geology71: 141–155.
