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McCulloch, D.S. and M.G. Bonilla. (1970). “Effects of the Earthquake of March 27, 1964, on the Alaska Railroad,” U.S. Geological Survey Professional Paper 545-D, USGS, 161 p.; and The Great Alaska Earthquake of 1964 – Geology, Part A, “Effects on the Alaska Railroad,” National Academy of Sciences, Washington, D.C. pp. 543- 640. McCullough, N.J. and S.E. Dickenson. 1998. “Estimation of Seismically-Induced Lateral Deformations for Anchored Sheetpile Bulkheads.” Proceedings from the 1998 ASCE Geotechnical Earthquake Engineering and Soil Dynamics Conference, Seattle, WA. pp. 1095- 1106. Meyerson, W.D., T.D. O'Rourke, and F. Miura. (1992). “Lateral Spread Effects on Reinforced Concrete Piles,” Proceedings, Fifth U.S.-Japan Workshop on Earthquake Disaster Prevention for Lifeline Systems, Tsukuba, Japan. Mitchell, J.K., H.G. Cooke, and J.A. Schaeffer. (1998). “Design Considerations in Ground Improvement for Seismic Risk Mitigation,” Proc. of the Geotechnical Earthquake Engineering and Soil Dynamics III, ASCE Geotechnical Special Publication 75(1):580-613. Miura, F. and T.D. O'Rourke. (1991). “Nonlinear Analyses of Piles Subjected to Liquefaction- Induced Large Ground Deformation,” Proceedings, Third Japan-U.S. Workshop on Earthquake- Resistant Design of Lifeline Facilities and Countermeasures for Soil Liquefaction, Technical Report NCEER-91-0001, State University of New York at Buffalo. pp 497-512. Moriwaki, Y., P. Tan, and J. Feng. (1998). “Seismic Deformation Analysis of the Upper San Fernando Dam Under the 1971 San Fernando Earthquake,” Proc. of the Geotechnical Earthquake Engineering and Soil Dynamics III, ASCE Geotechnical Special Publication 75(2):854-865. Muraleetharan, K.K., C. Mish, K. Yogachandran, and Arulanandan (1988). “DYSAC2: Dynamic Soil Analysis Code for 2-dimensional Problems,” Dept. of Civil Engineering, Univ. of California, Davis. Naesgaard, E., P.M. Bryne, G. Ven Huizen. (1998). “Behavior of Light Structures Founded on Soil ‘Crust’ Over Liquefied Ground,” Proc. of the Geotechnical Earthquake Engineering and Soil Dynamics III, ASCE Geotechnical Special Publication 75(1):422-433. National Research Council (NRC). (1985). “Liquefaction of Soils During Earthquakes,” National Research Council, National Science Foundation, Washington, D.C. 240 p. Newmark, N. (1965). “Effects of Earthquakes on Dams and Embankments.” Geotechnique 15(2):139-160. Oregon Board of Geologist Examiners/Oregon Board of Examiners for Engineering and Land Surveying (OBGE/OBEELS). (1997). “Guidelines for Site-specific Seismic Hazard Reports for Essential and Hazardous Facilities and Major and Special-occupancy Structures in Oregon,” Oregon Boards of Geologist Examiners and Examiners for Engineering and Land Surveying, Oregon Geology 59(1):6-8. 203
Oregon Department of Transportation (ODOT). (1996). “Liquefaction Mitigation Policy”, Oregon Department of Transportation, Bridge Engineering Section, Foundation Design Unit. 6 p. Olsen, R.S. 1997. “Cyclic Liquefaction Based on the Cone Penetrometer Test.” Proceeding of the NCEER Workshop on Evaluation of Liquefaction Resistance of Soils. Technical Report NCEER-97-0022, Salt Lake City, UT. pp.225-276. O’Rourke, T.D., W.D. Meyersohn, Y. Shiba, and D. Chaudhuri. (1994). “Evaluation of Pile Response to Liquefaction-Induced Lateral Spread,” Proceedings from the Fifth U.S.-Japan Workshop on Earthquake Resistant Design of Lifeline Facilities and Countermeasures Against Soil Liquefaction, Technical Report NCEER-97-0026, National Center for Earthquake Engineering Research, State University of New York at Buffalo. pp. 457-479. O'Rourke, T.D. and J.W. Pease. (1992). “Large Ground Deformations and Their Effects on Lifeline Facilities: 1989 Loma Prieta Earthquake,” Case Studies of Liquefaction and Lifeline Performance During Past Earthquake, Technical Report NCEER-92-0002, National Center for Earthquake Engineering Research, State University of New York at Buffalo. pp. 5.1-5.85. Plewes, M.D., E.C. McRoberts, and W.K. Chan. (1988). “Downhole Nuclear Density Logging in Sand Tailings,” Proceedings, ASCE Specialty Conference on Hydraulic Fill, Fort Collins, CO. pp. 290-309. Port and Harbour Research Institute (PHRI). (1997). “Handbook on Liquefaction Remediation of Reclaimed Land,” A.A. Balkema Publ., Brookfield, VT, 312 p. Poulos, S. (1981). “The Steady State of Deformation,” Journal of the Geotechnical Engineering Division 107(GT5):553-561. Poulos, S.J., G. Castro, and J.W. France. (1985). “Liquefaction Evaluation Procedure,” Journal of Geotechnical Engineering 111(6):772-791. Prakash, S., T. Guo, and S. Kumar. (1998). “Liquefaction of Silts and Silt-Clay Mixtures,” Proc. of the Geotechnical Earthquake Engineering and Soil Dynamics III, ASCE Geotechnical Special Publication 75(1):337-348. Prakash, S. and P. Dakoulas, editors. (1994). “Ground Failures Under Seismic Conditions,” ASCE Geotechnical Special Publication No. 44. 261 p. Rauch, A.F. and J.M. Martin. (2000). “EPOLLS Model for Predicting Average Displacements on Lateral Spreads,” Journal of Geotechnical and Geoenvironmental Engineering 126(4):360-371. Reese, L.C. and S. Wang. (1994). “Documentation of Computer Program LPILE,” Ensoft, Inc. Vers 4.0. Austin, TX, 366 p. Riemer, M.F., T.M. Lok, and J.K. Mitchell. (1996). “Evaluating Effectiveness of Liquefaction Remediation Measures for Bridges,” Proc. 6 th Japan-U.S. Workshop on Earthquake Resistant Design of Lifeline Facilities and Countermeasures Against Soil Liquefaction, National Center for Earthquake Engineering Research, Technical Report NCEER-96-0012. pp. 441-455. 204
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ASSESSMENT AND MITIGATION OF LIQUEF
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ACKNOWLEDGMENTS The authors would l
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ASSESSMENT AND MITIGATION OF LIQUEF
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8.0 HAZARD EVALUATION AND DEVELOPME
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LIST OF FIGURES Figure 1.1: ODOT’
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Figure 8.8: Long Valley Dam and Lak
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Design of a given component shall l
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Liquefaction Mitigation Procedure G
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Pacific Northwest also are summariz
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2.0 OVERVIEW OF LIQUEFACTION-INDUCE
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oughly 50 centimeters, with numerou
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supported bridges along the Seward
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Another area of extensive bridge da
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Nineteen bridges were also damaged
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1. No foundation failures were obse
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piles supporting the fourth pier, l
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Figure 2.17: Observed Pile Deformat
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Figure 2.19: Damage from the 1906 S
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Figure 2.22: Ground Deformations Ne
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induced ground displacement was the
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Well-documented case histories of t
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Similar damage to pile foundations
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Examples of acceptable bridge found
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Numerous investigations of liquefac
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3.0 EVALUATION OF LIQUEFACTION SUSC
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The evaluation of liquefaction haza
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Table 3.1: Estimated Susceptibility
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movements, or localized ground disp
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Shear wave velocities can now be ob
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3.4 LIQUEFACTION RESISTANCE: EMPIRI
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Figure 3.1: Range of r d Values for
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The earthquake-induced shearing str
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drill rod during hammer impact. In
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Figure 3.5: Minimum Values for K σ
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3.4.2.2.1 CPT Method Developed by R
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1. Sensitive, fine grained 6. Sands
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Figure 3.9: CPT-Based Curves for Va
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CRR where: q c 2 3 0.00128 0.0
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Tacoma, Washington (Dickenson and B
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Table 3.8: Influence of OCR on the
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Figure 3.13: Influence of Fines Con
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Gravel Sand Figure 3.16: Relationsh
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FS L > 1.4: Excess pore pressure ge
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The post-liquefaction strength of s
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Figure 4.3: Undrained Critical Stre
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4.3 INTRODUCTION TO MODES OF FAILUR
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Figure 4.5: (a) Relationship betwee
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not available for many case studies
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provided to give the recommended ra
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Figure 4.8: Overview of EPOLLS Mode
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Figure 4.10: Model of Hypothetical
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4.5.2 Advanced Numerical Modeling o
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Figure 4.12: Post Volumetric Shear
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The relationship shown in Figure 4.
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A third type of failure is shown in
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Table 5.1: Liquefaction Remediation
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5.3 DESIGN OF SOIL MITIGATION The d
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soil improvement guidelines state t
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The models were instrumented with a
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The model uses an explicit method,
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A simplification was made in the mo
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permanent earthquake displacements)
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7.0 DEFORMATION ANALYSIS OF EMBANKM
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engineers; (2) requisite input incl
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π g 2 a t I a 2 dt (7-1) The A
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10 1 Bracketed Intensity (m/s) 0.1
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7.3 PARAMETRIC STUDY A well-validat
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the rigid body methods. The point a
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0.4 Acceleration (g) 0.2 0 -0.2 -0.
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Embankment Height (m) Depth of Liqu
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10 1 DISPLACEMENT (m) 0.1 Morgan Hi
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2.0 Embankment Toe Embankment Mid-S
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suitably reliable estimates of perm
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interest. Specifically, the peak be
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Flow Chart for Evaluation and Mitig
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The deformation evaluations were pe
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Portland (a) (b) Figure 8.2: Illust
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Figure 8.4: Contours of PGA on Rock
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Borehole 4E CPT Hole 4E 26.0' NGVD
Page 165 and 166: 8.4.2 Subduction Zone Bedrock Motio
Page 167 and 168: 154 Table 8.5: Selected Acceleratio
Page 169 and 170: Spectral Acceleration (g) 1.50 1.40
Page 171 and 172: with the calculated equivalent unif
Page 173 and 174: n ( M 10 1) (8-1) where M is the
Page 175 and 176: 0.20 0.15 0.10 Acceleration (g) 0.0
Page 177 and 178: 15.0 12.5 10.0 Long Valley Dam Lake
Page 179 and 180: CSR should be modified for the pres
Page 181 and 182: 8.7 EVALUATION OF INITIATION OF LIQ
Page 183 and 184: crest stage Marine Drive 42.5 ft NG
Page 185 and 186: Table 8.9: Fines Content Values Est
Page 187 and 188: large sliding and long-term disrupt
Page 189 and 190: Table 8.12: Deformation Results fro
Page 191 and 192: The earthquake time histories used
Page 193 and 194: North (river) South (land) North To
Page 195 and 196: Table 8.20: Riverward Deformation R
Page 197 and 198: applications (DDC, closely spaced v
Page 199 and 200: Table 8.21: Comparison of Predicted
Page 202 and 203: 9.0 SUMMARY AND CONCLUSIONS Recent
Page 204: dewatering may be warranted. Additi
Page 207 and 208: Bardet, J.P. (1990). “LINOS - A N
Page 209 and 210: California Division of Mines and Ge
Page 211 and 212: Fujii, S., M. Cubrinovski, K. Tokim
Page 213 and 214: Ishihara, K. and M. Cubrinovski. (1
Page 215: Liu, A.H. and J.P. Stewart. (1999).
Page 219 and 220: Schnabel, P., J. Lysmer, and H.B. S
Page 221 and 222: Sun, I.H. and I.M. Idriss. (1992).
Page 223: Youd, T.L. and C.F. Jones. (1993).
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