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Your search keyword '"Kathleen M. Darby"' showing total 9 results
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9 results on '"Kathleen M. Darby"'

1. Effect of Partial Drainage on Cyclic Strengths of Saturated Sands in Dynamic Centrifuge Tests

Author

Ross W. Boulanger, Jason T. DeJong, and Kathleen M. Darby

Subjects
Centrifuge, Environmental Engineering, Cyclic strength, Geotechnical engineering, Drainage, Geotechnical Engineering and Engineering Geology, Geological & Geomatics Engineering, Civil Engineering, Geology, General Environmental Science
Abstract

The effects of partial drainage on the cyclic strength of saturated sand in a set of dynamic centrifuge model tests were evaluated. Three models of level profiles of saturated Ottawa F-65 sand with initial relative densities of 25%, 43%, and 80% were tested using a 9-m-radius centrifuge. Models were subjected to multiple sinusoidal shaking events with acceleration amplitudes ranging from 0.03g to 0.55g. The cyclic resistance ratios (CRR) obtained from inverse analyses of dense accelerometer and pore pressure transducer arrays were correlated with cone penetration resistances (qc1N) from in-flight cone penetration tests. Time histories of volumetric strain and surface settlement due to partial drainage were determined by inverse analyses of the array data and compared with measured surface settlements. The effect of volumetric strain on cyclic strength is examined through single-element simulations using the constitutive model PM4Sand version 3. Results of these simulations are compared to prior laboratory and numerical studies investigating the effect of partial saturation on cyclic strength. The magnitude of the volumetric strains developed in the centrifuge models due to partial drainage and their effects on the centrifuge CRR-qc1N correlation are examined.

Published
2019

2. Mechanistic development of CPT-based cyclic strength correlations for clean sand

Author

Adam B. Price, Ross W. Boulanger, Ana Maria Parra Bastidas, Kathleen M. Darby, Diane M. Moug, and Jason T. DeJong

Subjects
Environmental Engineering, Cone penetration test, Environmental science, Liquefaction, Geotechnical engineering, Cyclic strength, Geotechnical Engineering and Engineering Geology, Geological & Geomatics Engineering, Civil Engineering, General Environmental Science
Abstract

Mechanistic approaches to developing cone penetration test-based liquefaction triggering correlations are presented and evaluated with an application to Ottawa sand. The mechanistic approaches utilize combinations of data from undrained cyclic direct simple shear tests, dynamic geotechnical centrifuge tests with in-flight cone penetration profiles, and cone penetration simulations. Cyclic direct simple shear tests on Ottawa sand characterize the relationship between cyclic resistance ratio (CRR) and relative density (DR). Relationships between cone tip resistance (qc) and DR are developed from geotechnical centrifuge tests and cone penetration simulations. Penetration simulations using the MIT-S1 constitutive model with three different calibrations for Ottawa sand examine the role of critical state line shape and position on simulated qc values. The CRR-DR relationship from laboratory tests is composed with measured and simulated qC-DR relationships via common DR values to develop CRR-qc relationships. An alternative CRR-qc relationship is developed from inverse analyses of centrifuge test sensor array data (i.e., arrays of accelerometers and pore pressure sensors). The results of these different approaches are compared to case history-based correlations for clean sand and their relative merits discussed. Recommendations are provided for future application of these mechanistic approaches to developing liquefaction-triggering correlations of poorly characterized or unique soils.

Published
2019

3. Centrifuge Model Testing of Liquefaction Mitigation via Microbially Induced Calcite Precipitation

Author

Gabby L. Hernandez, Michael G. Gomez, Ross W. Boulanger, Kathleen M. Darby, Jason T. DeJong, and Daniel W. Wilson

Subjects
Calcite, 021110 strategic, defence & security studies, Centrifuge, Environmental Engineering, Precipitation (chemistry), 0211 other engineering and technologies, Mineralogy, Liquefaction, 02 engineering and technology, Radius, Geological & Geomatics Engineering, Geotechnical Engineering and Engineering Geology, Civil Engineering, chemistry.chemical_compound, chemistry, Model testing, Environmental science, Geotechnical engineering, 021101 geological & geomatics engineering, General Environmental Science
Abstract

A set of saturated Ottawa sand models was treated with microbially induced calcite precipitation (MICP) and subjected to repeated shaking events using the 1-m radius centrifuge at the UC Davis Center for Geotechnical Modeling. Centrifuge models were constructed to initial relative densities (DR0) of approximately 38% and treated to light, moderate, and heavy levels of cementation (calcium carbonate contents by mass of approximately 0.8%, 1.4%, and 2.2%, respectively) as indicated by shear wave velocities (light≈200 m/s, moderate≈325 m/s, and heavy≈600 m/s). The cemented centrifuge models were compared to a pair of uncemented saturated Ottawa sand models with initial DR0≈38 and 53% and subjected to similar levels of shaking. Cone penetration resistances and shear wave velocities were monitored throughout shaking to investigate (1) the effect of cementation on cone penetration resistance, shear wave velocity, and cyclic resistance to liquefaction triggering; and (2) the effect of shaking on cementation degradation. Accelerometers, pore pressure transducers, and a linear potentiometer were used to monitor the effect of cementation on liquefaction triggering and consequences. Cone penetration resistances and shear wave velocities were sensitive to light, moderate, and heavy levels of cementation (increases in penetration resistance from 2 to 5 MPa, from 2 to 10 MPa, and from 2 to 18 MPa and increases in shear wave velocity from 140 to 200 m/s, from 140 to 325 m/s, and from 140 to 660 m/s, respectively), and were able to capture the effects of cementation degradation.

Published
2019
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4. Progressive Changes in Liquefaction and Cone Penetration Resistance across Multiple Shaking Events in Centrifuge Tests

Author

Ross W. Boulanger, Jason T. DeJong, Kathleen M. Darby, and Jaclyn D. Bronner

Subjects
021110 strategic, defence & security studies, Centrifuge, Materials science, Environmental Engineering, genetic structures, 0211 other engineering and technologies, Liquefaction, 02 engineering and technology, Penetration (firestop), Geotechnical Engineering and Engineering Geology, Geological & Geomatics Engineering, Civil Engineering, Cone penetration test, Geotechnical engineering, sense organs, 021101 geological & geomatics engineering, General Environmental Science
Abstract

The effects of shaking history on cone penetration test (CPT)-based liquefaction triggering correlations for clean saturated sand are examined by using cone penetration resistance and cyclic strength data pairs from dynamic centrifuge model tests. Three model tests on a 9-m-radius centrifuge examined the liquefaction responses of level profiles of saturated Ottawa F-65 sand subjected to multiple (17-29) shaking events that produced successive changes in density and model response characteristics. Inverse analysis of data from dense accelerometer arrays were used to define time series of cyclic stress ratios and shear strains throughout the profile. Cyclic resistance ratios against triggering of ~100% excess pore pressure ratio in 15 equivalent uniform cycles were computed at multiple depths based on weighting of the cyclic stress ratio time series up to the time of triggering. Cone penetration tests performed at select times during each model test were used to define the variation in cone tip resistances with depth and shaking history. The resulting data pairs, with normalized cone tip resistances ranging from 20 to 340 and cyclic resistance ratios ranging from 0.1 to 2.0, show that both quantities progressively increase as a result of recurrent liquefaction events and generally follow the trends predicted by case history-based liquefaction triggering correlations. Three 1-m-radius centrifuge tests of similar configurations produced consistent results. Implications for the interpretation of case histories and engineering practice are discussed.

Published
2019

6. Volumetric Strains from Inverse Analysis of Pore Pressure Transducer Arrays in Centrifuge Models

Author

Jason T. DeJong, Ross W. Boulanger, and Kathleen M. Darby

Subjects
021110 strategic, defence & security studies, Centrifuge, Materials science, 0211 other engineering and technologies, Liquefaction, 02 engineering and technology, Radius, Mechanics, Dissipation, Pore water pressure, Acceleration, Amplitude, Transducer, 021101 geological & geomatics engineering
Abstract

Inverse analyses were used to evaluate the degree of partial drainage occurring during dynamic shaking of liquefying soil profiles in a set of centrifuge model tests. Three tests were performed using the 9-m radius centrifuge at the UC Davis Center for Geotechnical Modeling on saturated Ottawa sand models with initial relative densities of 25, 43, and 80%. Models were subjected to multiple sinusoidal shaking events with acceleration amplitudes ranging from 0.03 to 0.55g. Densely spaced pore pressure transducer arrays provided profiles of pore pressure generation and dissipation; inverse analyses of the pore pressure data were used to obtain volumetric strain profiles during shaking and dissipation. Surface settlements computed by integrating the volumetric strain profiles are compared to surface settlements measured from linear potentiometers. The magnitude of the volumetric strains due to partial drainage and their potential effects on liquefaction responses are discussed.

Published
2018
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7. Centrifuge Model Testing of Liquefaction Mitigation via Denitrification-Induced Desaturation

Author

Daniel W. Wilson, Jason T. DeJong, Leon A. van Paassen, Caitlyn Hall, Kathleen M. Darby, Gabby L. Hernandez, and Edward Kavazanjian

Subjects
021110 strategic, defence & security studies, Centrifuge, Denitrification, Model testing, 0211 other engineering and technologies, Environmental science, Liquefaction, Geotechnical engineering, 02 engineering and technology, 021101 geological & geomatics engineering
Published
2018
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