Sensitivity of Liquefaction Triggering Analysis to Earthquake Magnitude

Similar documents
Liquefaction Hazard Maps for Australia

Screening-Level Liquefaction Hazard Maps for Australia

Liquefaction Assessment using Site-Specific CSR

Guidance for the CPT-Based Assessment of Earthquakeinduced Liquefaction Potential in Australia, with a Focus on the Queensland Coast

PERFORMANCE-BASED LIQUEFACTION POTENTIAL: A STEP TOWARD MORE UNIFORM DESIGN REQUIREMENTS

Liquefaction assessments of tailings facilities in low-seismic areas

Bayesian Methods and Liquefaction

THE OVERPREDICTION OF LIQUEFACTION HAZARD IN CERTAIN AREAS OF LOW TO MODERATE SEISMICITY

ASSESSMENT OF SEISMIC RISK FOR THE DESIGN OF OFFSHORE STRUCTURES IN LIQUEFIABLE SOIL

A NEW SIMPLIFIED CRITERION FOR THE ASSESSMENT OF FIELD LIQUEFACTION POTENTIAL BASED ON DISSIPATED KINETIC ENERGY

Improved Liquefaction Hazard Evaluation through PLHA. Steven L. Kramer University of Washington

Nonlinear shear stress reduction factor (r d ) for Christchurch Central Business District

LIQUEFACTION ASSESSMENT OF INDUS SANDS USING SHEAR WAVE VELOCITY

Evaluation of soil liquefaction using the CPT Part 1

LIQUEFACTION POTENTIAL & POST EARTHQUAKE STABILITY ASSESSMENT. H2J Engineering

Date: April 2, 2014 Project No.: Prepared For: Mr. Adam Kates CLASSIC COMMUNITIES 1068 E. Meadow Circle Palo Alto, California 94303

Earthquake-induced liquefaction triggering of Christchurch sandy soils

Liquefaction Evaluation

The LSN Calculation and Interpolation Process

Assessment of Risk of Liquefaction - A Case Study

Evaluation of Geotechnical Hazards

Cyclic Softening of Low-plasticity Clay and its Effect on Seismic Foundation Performance

NEW METHOD FOR LIQUEFACTION ASSESSMENT BASED ON SOIL GRADATION AND RELATIVE DENSITY

1.1 Calculation methods of the liquefaction hazard.

The Travails of the Average Geotechnical Engineer Using the National Seismic Hazard Maps

SEISMIC LIQUEFACTION ANALYSIS OF CAPITAL REGION OF ANDHRA PRADESH STATE, INDIA

Comparison of Three Procedures for Evaluating Earthquake-Induced Soil Liquefaction

Liquefaction-Induced Ground Deformations Evaluation Based on Cone Penetration Tests (CPT)

Liquefaction Risk Potential of Road Foundation in the Gold Coast Region, Australia

CYCLIC SOFTENING OF LOW-PLASTICITY CLAY AND ITS EFFECT ON SEISMIC FOUNDATION PERFORMANCE

CPT-BASED SIMPLIFIED LIQUEFACTION ASSESSMENT BY USING FUZZY-NEURAL NETWORK

LATERAL CAPACITY OF PILES IN LIQUEFIABLE SOILS

(THIS IS ONLY A SAMPLE REPORT OR APPENDIX OFFERED TO THE USERS OF THE COMPUTER PROGRAM

LSN a new methodology for characterising the effects of liquefaction in terms of relative land damage severity

Liquefaction Hazard Mapping. Keith L. Knudsen Senior Engineering Geologist California Geological Survey Seismic Hazard Mapping Program

AGMU Memo Liquefaction Analysis

A surface seismic approach to liquefaction

EARTHQUAKE-INDUCED SETTLEMENTS IN SATURATED SANDY SOILS

PROBABILISTIC SEISMIC HAZARD ANALYSES AND DEAGGREGATION FOR MAPPING LIQUEFACTION AND EARTHQUAKE-INDUCED LANDSLIDE HAZARD ZONES

Evaluating the Seismic Coefficient for Slope Stability Analyses

Evaluation of soil liquefaction using the CPT Part 2

Comparison of different methods for evaluating the liquefaction potential of sandy soils in Bandar Abbas

Methods for characterising effects of liquefaction in terms of damage severity

DIFFICULTIES IN ASSESSING LIQUEFACTION POTENTIAL FROM CONVENTIONAL FIELD TESTING

Session 2: Triggering of Liquefaction

Evaluation of liquefaction resistance of non-plastic silt from mini-cone calibration chamber tests

2-D Liquefaction Evaluation with Q4Mesh

Verifying liquefaction remediation beneath an earth dam using SPT and CPT based methods $

Determination of Liquefaction Potential By Sub-Surface Exploration Using Standard Penetration Test

Evaluation of the liquefaction potential of soil deposits based on SPT and CPT test results

Liquefaction Potential Post-Earthquake in Yogyakarta

SOME OBSERVATIONS RELATED TO LIQUEFACTION SUSCEPTIBILITY OF SILTY SOILS

Fines Content Correction Factors for SPT N Values Liquefaction Resistance Correlation

Ground Motion Comparison of the 2011 Tohoku, Japan and Canterbury earthquakes: Implications for large events in New Zealand.

LIQUEFACTION POTENTIAL ASSESSMENT BASED ON LABORATORY TEST

Prediction of earthquake-induced liquefaction for level and gently

SEISMIC SOIL LIQUEFACTION BASED ON IN SITU TEST DATA

Liquefaction induced ground damage in the Canterbury earthquakes: predictions vs. reality

Using GIS Software for Identification and Zoning of the Areas Prone to Liquefaction in the Bed Soil of the Dams

PORE PRESSURE GENERATION UNDER DIFFERENT TRANSIENT LOADING HISTORIES

Investigation of Liquefaction Behaviour for Cohesive Soils

Assessment of cyclic liquefaction of silt based on two simplified procedures from piezocone tests

Evaluation of Seismic Response of a Site Class F Site Using Equivalent Linear and Nonlinear Computer Codes

SHEAR WAVE VELOCITY-BASED LIQUEFACTION RESISTANCE EVALUATION: SEMI-THEORETICAL CONSIDERATIONS AND EXPERIMENTAL VALIDATIONS

CPT Applications - Liquefaction 2

Address for Correspondence

A CASE STUDY OF LIQUEFACTION ASSESSMENT USING SWEDISH WEIGHT SOUNDING

Short Review on Liquefaction Susceptibility

Micro Seismic Hazard Analysis

Semi-empirical procedures for evaluating liquefaction potential during earthquakes

Liquefaction and Foundations

Seismic site response analysis for Australia

Probabilistic evaluation of liquefaction-induced settlement mapping through multiscale random field models

Geotechnical issues in seismic assessments: When do I need a geotechnical specialist?

LIQUEFACTION CHARACTERISTICS EVALUATION THROUGH DIFFERENT STRESS-BASED MODELS: A COMPARATIVE STUDY

Consideration of Ground Variability Over an Area of Geological Similarity as Part of Liquefaction Assessment for Foundation Design

PROCEDURE TO EVALUATE LIQUEFACTIO -I DUCED SETTLEME T BASED O SHEAR WAVE VELOCITY. Fred (Feng) Yi 1 ABSTRACT

GUIDANCE D. Part D: Guidelines for the geotechnical investigation and assessment of subdivisions in the Canterbury region.

OVERBURDEN CORRECTION FACTORS FOR PREDICTING LIQUEFACTION RESISTANCE UNDER EMBANKMENT DAMS

SEISMIC HAZARD ANALYSIS. Instructional Material Complementing FEMA 451, Design Examples Seismic Hazard Analysis 5a - 1

A Unique Experience with Liquefaction Assessment of Impounded Brown Coal Ash

Numerical analysis of effect of mitigation measures on seismic performance of a liquefiable tailings dam foundation

Probabilistic Earthquake Risk Assessment of Newcastle and Lake Macquarie Part 1 Seismic Hazard.

Liquefaction Hazards for Seismic Risk Analysis

Correction of Mechanical CPT Data for Liquefaction Resistance Evaluation

Performance based earthquake design using the CPT

Liquefaction Potential Variations Influenced by Building Constructions

Liquefaction potential of Rotorua soils

Seismic Evaluation of Tailing Storage Facility

Evaluation of the Liquefaction Potential by In-situ Tests and Laboratory Experiments In Complex Geological Conditions

Comparison between predicted liquefaction induced settlement and ground damage observed from the Canterbury earthquake sequence

Case Study - Undisturbed Sampling, Cyclic Testing and Numerical Modelling of a Low Plasticity Silt

Use of CPT in Geotechnical Earthquake Engineering

Overview of screening criteria for liquefaction triggering susceptibility

Performance and Post Earthquake Assessment of CFA Pile Ground Improvement 22 February 2011 Christchurch, New Zealand Earthquake

FRIENDS OF THE EEL RIVER

Centrifuge Evaluation of the Impact of Partial Saturation on the Amplification of Peak Ground Acceleration in Soil Layers

Module 6 LIQUEFACTION (Lectures 27 to 32)

A DEVELOPED PROCEDURE FOR PREDICTING THE RISK OF LIQUEFACTION: A CASE STUDY OF RASHT CITY

Assessment of the Potential for Earthquake- Induced Liquefaction in Granular Soils

Transcription:

Australian Earthquake Engineering Society 2013 Conference, Nov 15-17, Hobart, Tasmania Sensitivity of Liquefaction Triggering Analysis to Earthquake Magnitude Dr Timothy I Mote 1 and Minly M. L. So 2 1. Corresponding Author. Associate, Arup, 201 Kent St. Lvl 10, Sydney, New South Wales Email: tim.mote@arup.com 2. Seismic Specialist, Arup, 201 Kent St. Lvl 10, Sydney, New South Wales Email: minly.so@arup.com ABSTRACT Application of liquefaction triggering analysis with design ground motions derived from a probabilistic seismic hazard analysis (PSHA), as in AS1170.4 (2007) or most modern seismic codes, requires selection of an appropriate design earthquake magnitude. Guidance on selection of appropriate design earthquake magnitudes is often directed by the seismic code as the maximum considered earthquake (ASCE 7-10) or from a magnitude distance deaggregation (CalTrans 2012). Where guidance is lacking the selection process is based on professional judgment. This paper explores the sensitivity of selection of earthquake design magnitude to liquefaction triggering factor of safety in the context of liquefaction assessments in Australia following AS1170.4 (2007) where guidelines for design earthquake magnitudes for liquefaction are not specified. The assessment shows that following the simplified liquefaction trigger analysis methodology (Seed and Idriss, 1971) very loose to loose saturated sands, would liquefy regardless of the design magnitude selected and high importance sites on medium dense saturated sands would also liquefy regardless of the design magnitude selected. The assessment also shows that liquefaction triggering analysis is very sensitive to the design magnitude selected for normal importance sites on loose to medium dense sands. Keywords: sensitivity Liquefaction triggering analysis, earthquake design magnitude, AS1170.4, 1. INTRODUCTION Although Australia is considered a stable continental region and seismic hazard is relatively low compared to active tectonic areas of the world, earthquakes do occur and where susceptible geological conditions exit with high groundwater, liquefaction can occur. As such liquefaction is a credible geohazard considered in current Australian geotechnical engineering practice.

Liquefaction triggering analysis methodology has been well established in earthquake engineering practice following Seed and Idriss (1971) and refinements over the last 40 years. These assessments use four critical input parameters; soil properties and groundwater conditions to estimate liquefaction triggering potential as a cyclic resistance ratio (CRR) and ground motions with earthquake magnitude reflecting cycles to estimate a cyclic stress ratio (CSR). In active seismic regions around the world, local seismic design code often provides guidance on liquefaction analysis, specifically the selection of appropriate design earthquake magnitudes to estimate a CSR. For example ASCE 7-10 recommends using the maximum considered earthquake (MCE) and post-canterbury Earthquake practice in NZ following NZS1170.5 and MBIE 2012 guidelines specify M7.5 for all liquefaction calculations regardless of the importance level.. Where design magnitudes are not explicitly provided by code, the common method for selecting magnitude is to consider earthquake scenarios that contribute the greatest amount to the ground motion hazard (CalTrans 2012). This is done by examination of the magnitude deaggregation of a probabilistic seismic hazard analysis (PSHA). In Australian practice, ground motions provided in the AS1170.4 (2007) are from McCue et al. (1993) using PSHAs conducted by Gaull et al. (1990) and many others. AS1170.4 (2007) does not provide enough information to readily extract earthquake design magnitudes or to compute magnitude deaggregation. As a result, earthquake engineering practitioners in Australia have applied a number of different methodologies to assign earthquake design magnitude for site-specific studies. These methods range from estimating mean values from regional recurrence curves (Mitchell and Moore, 2007), using the maximum historic earthquake in Australia for a given region, consideration of a range of magnitudes (Yang and Wright, 2010) or choosing a conservative magnitude based on professional judgment. None of these methods are directly compatible with AS1170.4 (2007) as they do not include ground motion variability, which is a hallmark attribute of PSHA. The sensitivity in selecting design magnitude for use in Australia limits the rigor in liquefaction triggering analysis in Australian. To address this Mote and Dismuke (2011) developed an approximate magnitude distance deaggregation of the PSHA used to develop the hazard map in AS1170-4 (2007). This study addresses the sensitivity of liquefaction triggering analysis based on selection of design magnitudes within ground motions provided by AS1170.4 (2007). 2. LIQUEFACTION TRIGGERING ANALYSIS METHODOLOGY Seed and Idriss (1971) proposed a simplified procedure for evaluation of liquefaction triggering that compare the soils resistance to liquefaction with the cyclic stress caused by an earthquake, expressed as the factor of safety against triggering liquefaction, FS liq. The resistance to liquefaction, commonly termed cyclic resistance ratio (CRR), depends on the relationship between the in-situ density of the soil with its critical state, as well as the behavior of the soil under earthquake-induced cyclic loading. The driving cyclic stress caused by an earthquake is commonly termed cyclic stress ratio (CSR). CSR used in the simplified procedure for liquefaction triggering analysis is the ratio of average, or equivalent, shear stress induced by the earthquake to the in-situ effective vertical stress. Seed and Idriss (1971) proposed that the average equivalent CSR for liquefaction triggering assessment is about 0.65 times the peak shear stress, and may be estimated as:

v CSR 0.65 Amax r ' d v Where σ v is the total vertical stress, σ v is the effective vertical stress, A max is the maximum acceleration (taken as peak ground acceleration (PGA), and r d is the nonlinear shear-mass participation factor. While A max defines the maximum ground acceleration it provides no information on the duration of shaking. The importance of design magnitude in liquefaction assessments is the provision of an indication of duration of shaking or the number of strong motion cycles. The convention for assessing liquefaction triggering is to determine CSR normalized to the duration of a M7.5 earthquake, denoted CSR 7.5. This is achieved by modifying the CSR by a magnitude-duration weighting factor, DWF after Idriss and Boulanger (2008). DWF is calculated as: DWF = (6.9*EXP(-M / 4)-0.058) The magnitude-duration weighted cyclic stress ratio, CSR 7.5, is calculated as: CSR 7.5 = CSR / DWF And the factor of safety against triggering liquefaction is: FS liq = CRR/CSR Values for CRR come from the boundary curve drawn through CSR-data from liquefaction and non-liquefaciton case histories. A FS liq less than 1.0 implies that liquefaction triggering is likely. 3. METHODOLOGY This study applies a range of design magnitudes to ground motions derived from AS1170-4 (2007) for two Site Soil Subclasses to understand the sensitive of liquefaction triggering to earthquake magnitude. Liquefaction and no-liquefaction case history databases recently used by Cetin et al. (2004), Moss et al. (2006) and Idriss and Boulanger (2008) for SPT and CPT-based triggering assessment procedures indicate the minimum CSR 7.5 where liquefaction was observed is about 0.05 for very loose to loose saturated sand and about 0.1 for loose to medium dense saturated sand. For this study we assume a CRR for Site Soil Subclass D and E as follows: Loose to medium dense sands (Site Soil Subclass D) - CRR = 0.1 Very loose to loose sands (Site Soil Subclass E) - CRR = 0.05 The ground motions, A max, are taken as minimum and maximum of Z values and scaled accordingly for Importance Levels 2, 3 and 4 (k p ) and respective spectral shape factor for the appropriate Site Soil Subclass (C h ) following AS1170-4 (2007). Amax = Z k p C h

The DWF calculation is iterated on magnitudes at 0.1 intervals from 5 to 7.5. Finally, FS liq is calculated for all Z values between 0.05 and 0.1, Importance Levels 2, 3, & 4, and Site Soil Subclass D & E. 4. RESULTS Figure 1 to 6 show FS liq for a range of Z values plotted against Magnitude for Class D (CRR = 0.1) and Class E (CRR = 0.05) with Importance Levels 2, 3 &4. Where FS liq is less than 1 the soil is considered liquefiable. Figure 1 FS liq for a range of Z values for Class D (CRR = 0.1) and Importance Level 2

Figure 2 FS liq for a range of Z values for Class D (CRR = 0.1) and Importance Level 3 Figure 3 FS liq for a range of Z values for Class D (CRR = 0.1) and Importance Level 4

Figure 4 FS liq for a range of Z values for Class E (CRR = 0.05) and Importance Level 2 Figure 5 FS liq for a range of Z values for Class E (CRR = 0.05) and Importance Level 3

Figure 6 FS liq for a range of Z values for Class E (CRR = 0.05) and Importance Level 3 5. CONCLUSIONS AND DISCUSSION The results show that the liquefaction triggering analysis for very loose to loose saturated sand) have a CRR low enough that liquefaction will likely trigger under any design magnitude for all anticipated ground motions in Australia and is not sensitive to design magnitude for all Importance Levels (Figure 4, 5, and 6). Loose to medium dense saturated sands also will likely trigger liquefaction and are not sensitive to design magnitude for Importance Level 4 (Figures 3 and 6) for all anticipated ground motions in Australia. For loose to medium dense saturated sands (Site Soil Subclass D) at Importance Level 2 and Level 3, the results show that the selection of magnitude is sensitive to triggering analysis for a number of anticipated ground motions in Australia (Figures 1 and 2). That is, the selection of magnitude for lower Importance Levels in loose to medium dense saturated sands will control whether the liquefaction will trigger or not. It is important for earthquake engineering practitioners in Australia to understand the sensitivity to design magnitude selection. When performing liquefaction triggering analysis on Importance Level 2 or 3 sites founded in loose to medium dense saturated sands, deterministic selection of design magnitudes such as from maximum magnitude estimates (Clark et al., 2010) or from magnitude distance deaggregation (Mote and Dismuke, 2011) should be considered.

6. REFERENCES Australian Standards Australia, 2007. Structural design actions, part 4: Earthquake actions in Australia. Standards Australia. Cetin, K.O., Seed, R.B., Der Kiureghian, A., Tokimatsu, K., Harder, L.F., Kayen, R.E., and Moss, R.E.S., 2004. Standard penetration test-based probabilistic and deterministic assessment of seismic soil liquefaction potential, Journal of Geotechnical and Geoenvironmental Engineering, ASCE 130(12), 1314-340. Clark, D., McPherson, A., and Collins, C., 2010. Mmax estimates for the Australian stable continental region (SCR) derived from palaeoseismicity data. AEES 2010 Gaull, B.A., Michael-Leiba, M.O., and Rynn, J.M.W., 1990. Probabilistic earthquake risk maps of Australia. Australian Journal of Earth Sciences 37, 169-187. Idriss, I.M., and Boulanger, R.W., 2008. Soil Liquefaction During Earthquakes, monograph series, No. MNO-12, Earthquake Engineering Research Institute. McCue, K., (Compiler), Gibson, G., Michael-Leiba, M., Love, D., Cuthbertson, R., & Horoschun, G., 1993. Earthquake hazard map of Australia, 1991. Mitchell P. W. and Moore C. 2007, Difficulties in assessing liquefaction potential from conventional field testing. AEES 2007 Moss, R.E.S., Seed, R.B., Kayen, R.E., Stewart, J.P., Der Kiureghian, A., and Cetin, K.O., 2006. CPT-based probabilistic and deterministic assessment of in situ seismic soil liquefaction potential, Journal of Geotechnical and Geoenvironmental Engineering, ASCE 132(8), 1032-051. Mote T. I. and Dismuke J., 2011. Screening Level Liquefaction Hazard Maps for Australia AEES 2011 Seed, H. B., and Idriss, I. M., 1971. Simplified procedure for evaluating soil liquefaction potential. Journal of the Geotechnical Engineering Division, ASCE, 97(9), 1249 1273.

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback