Abstract
The 11 March 2011 East Japan Earthquake and Tsunami caused unprecedented damage to well-engineered buildings and coastal structures. This report presents some notable field observations of structural damage based on our surveys conducted along the Sanriku coast in April and June 2011. Engineered reinforced concrete buildings failed by rotation due to the high-velocity and deep tsunami inundation: entrapped air in the buildings and soil liquefaction by ground shaking could have contributed to the failure. The spatial distribution pattern of destroyed and survived buildings indicates that the strength of tsunami was affected significantly by the locations of well-engineered sturdy buildings: weaker buildings in the shadow zone tended to survive while jet and wake formations behind the sturdy buildings enhanced the tsunami forces. We also found that buildings with breakaway walls or breakaway windows/doors remained standing even if the surrounding buildings were washed away or destroyed. Several failure patterns of coastal structures (seawalls) were observed. Flow-induced suction pressure near the seawall crown could have caused the failure of concrete panels that covered the infill. Remarkable destruction of upright solid-concrete type seawalls was closely related with the tsunami induced scour and soil instability. The rapid decrease in inundation depth during the return-flow phase caused soil fluidization down to a substantial depth. This mechanism explains severely undermined roads and foundations observed in the area of low flow velocities.
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References
Abe, Kuniaki., Abe, Katsuyuki, Tsuji, Y., Imamura, F., Katao, H., Iio, Y., Satake, K., Bourgeois, J., Noguera, E., and Estrada, F. (1993) Fields survey of the Nicaragua Earthquake and Tsunami of September 2, 1992. Bill. Earthq. Res. Inst., Univ. Tokyo, vol. 68, 23–70.
Carslaw, H.S. and Jaeger, J.C., (1959). Conduction of Heat in Solids. Oxford University Press, Oxford, 510 pp.
Dalrymple, R.A., and Kriebel, D.L. (2005), Lessons in engineering from the tsunami in Thailand. The Bridge, 35, 4–13.
ERI: Earthquake Research Institute (2011). http://outreach.eri.u-tokyo.ac.jp/eqvolc/201103_tohoku/eng/
Fritz, H.M., Phillips, D.A., Okayasu, A., Shimozono, T., Liu, H., Mohammed, F., Skanavis, V., Synolakis, C.E., and Takahashi, T. (2012) The 2011 Japan tsunami current velocity measurements from survivor videos at Kesennuma Bay using LiDAR. Geophy. Res. Lett., 39, L00G23, doi:10.1029/2011GL050686.
Ghobarah, A., Saatcioglu, M., and Nistor, I. (2006). The impact of the 26 December 2004 earthquake and tsunami on structure and infrastructure. Engineering Structures, 28 (2), 312–326.
Henderson, F.M. (1966). Open Channel Flow. Macmillan Co., New York, New York, 522 pp.
Iida, K. (1984), Catalog of tsunamis in Japan and its neighboring countries. Special Report, Aichi Institute of Technology, 52 pp.
Joint Survey Group: The 2011 Tohoku Earthquake Tsunami Joint Survey Group (2011). Nationwide field survey of the 2011 off the Pacific coast of Tohoku Earthquake Tsunami, J. Jap. Soc. Civil Eng., B. 67(1), 63–66.
Kato, F., Sato, S. and Yeh, H. (2000), Large-Scale Experiment on Dynamic Response of Sand Bed around a Cylinder due to Tsunami, Coastal Engineering 2000, ASCE, 1848–1859.
Koshimura, S. (2011), Field survey of the 2011 tsunami inundation in Tohoku District: towards comprehensive understanding of tsunami disaster. Pre-publication report presented in Takatsuki, Japan, July, 2011.
Lighthill, J. (1978). Waves in Fluids. Cambridge University Press, 504 pp.
PARI: Port and Airport Research Institute, (2011). Urgent Survey of 2011 Great East Japan Earthquake and Tsunami Disaster in Ports and Coasts. Technical Note No. 1231.
Reese, S., Bradley, B.A., Bind, J., Smart, G., Power, W., and Sturman, J. (2011). Empirical building fragilities from observed damage in the 2009 South Pacific tsunami. Earth-Science Review, 107, 156–173.
Shuto, N. (1994). Building damage evaluation for the 1993 Okushiri tsunamis, Tsunami Engineering Technical Report No.11, DCRC, Tohoku University, 11–28 (in Japanese).
Synolakis, C.E. (1991). Green’s law and the evolution of solitary waves, Phys. Fluids A 3(3), 490–492.
Takahashi, R. and Hatori, T. (1961). A summary report on the Chilean tsunami of May 1960. Report on the Chilean Tsunami, Field Investigation Committee for Chilean Tsunami. Dec. 1961.
Takahashi, T. (2011). Mechanism of Tsunami. Parity, 26(11), 34–41 (in Japanese).
Terzaghi, K. (1925). Erdbaumechanik (in German). Franz Deutike, Vienna.
Tonkin, S., Yeh, H., Kato, F., and Sato S. (2003). Tsunami Scour around a Cylinder: an Effective Stress Approach, Journal of Fluid Mechanics, 496, 165–192.
USGS (2010). http://earthquake.usgs.gov/earthquakes/world/events/.
Video (2011): http://www.youtube.com/watch?v=2lnMZIRbLjM; http://www.youtube.com/watch?v=XbdCwe8agRQ&feature=related.
Yeh, H. (1995). Tsunami Reconnaissance Procedures. Proceedings of the 27th Joint Meeting of US-Japan Panel on Wind and Seismic Effects, Tsukuba, Japan. 527–544.
Yeh, H. (2007), Design tsunami forces for onshore structures, J. Disaster Research, 2. 531–536.
Yeh (2009). Tsunami impact on coastlines. In: The Sea, Tsunamis (Ed: E.N. Bernard and A.R. Robinson), Harvard Univ. Press, 333–369.
Yeh, H., Kato, F., and Sato, S. (2001). Tsunami scour mechanisms around a cylinder. Tsunami Research at the End of a Critical Decade (Ed: G.T. Hebenstreit), Kluwer Academic Publishers. 33–46.
Yeh, H., Tonkin, S., Heller, E., Arduino, P., Kato, F., and Sato, S. (2004). Mechanisms of scour induced by tsunami runup. Proceedings of Second International Conference on SCOUR and EROSION, Singapore. Vol. 2, 464–471.
Yeh, H., Francis, M., Peterson, C., Katada, T., Latha, G., Chadha, R.K., Singh, J.P., and Raghuraman, G. (2007). Effects of the 2004 Great Sumatra Tsunami: Southeast Indian Coast, Journal of Waterway, Port, Coastal, and Ocean Engineering, 133, 382–400.
Yeh, H., Sato, S. and Tajima, Y. (2011). Waveform evolution of the 2011 East Japan Tsunami. In: Asian and Pacific Coasts 2011: Proceedings of the 6th International Conference on APAC 2011 (Ed: Lee, J. H.-W. and Ng, C.O.), World Scientific, Singapore. 131–138.
Acknowledgments
Greg Deierlein made a preliminary estimate for the size, weight, and the entrapped-air effect of the building shown in Fig. 2d, and Philip Liu gave useful inputs through our discussions. Yusuke Yamanaka and Hideyuki Nakao helped collect data in our June survey. This work was supported by the US National Science Foundation RAPID Program (1137811 and 1135768), the Oregon State University Edwards Endowment, and the Japan Science and Technology Foundation J-RAPID Program.
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Yeh, H., Sato, S. & Tajima, Y. The 11 March 2011 East Japan Earthquake and Tsunami: Tsunami Effects on Coastal Infrastructure and Buildings. Pure Appl. Geophys. 170, 1019–1031 (2013). https://doi.org/10.1007/s00024-012-0489-1
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DOI: https://doi.org/10.1007/s00024-012-0489-1