Field Monitoring of the Persistence of Microbially Induced Desaturation for Mitigation of Earthquake Induced Soil Liquefaction in Silty Soil

K. Sorenson; A. M. Preciado; D. Moug; A. Khosravifar; L. Van Paassen; E. Kavazanjian; K. Stokoe; F. Menq

doi:10.1061/9780784484449.009

Field Monitoring of the Persistence of Microbially Induced Desaturation for Mitigation of Earthquake Induced Soil Liquefaction in Silty Soil

K. Sorenson, A. M. Preciado, D. Moug, A. Khosravifar, L. Van Paassen, E. Kavazanjian, K. Stokoe, F. Menq

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

1 Scopus citations

Abstract

Earthquake liquefaction hazards in silty soils are a critical problem in Portland, Oregon, and other areas around the world. Recent studies suggest that liquefaction mitigation using microbially induced desaturation (MID) may provide the capability to mitigate liquefaction potential beneath existing structures in a cost-effective manner. The objective of MID is to reduce earthquake-induced excess pore water pressure generation compared to saturated soil, and thereby reduce the potential for triggering liquefaction. A field study of liquefaction mitigation using MID was performed at two sites in Portland in the summer of 2019. Low-plasticity, liquefiable silts were treated with MID by injecting a treatment solution to stimulate native bacteria for a duration of four weeks. This paper presents monitoring data that evaluate the level of desaturation before, during and after the completion of the MID trials. Monitoring included crosshole pressure-wave velocity measurements, a vertical array of embedded sensors that measure water content and bulk electrical conductivity, pre- and post-treatment seismic cone penetration tests, and direct soil sampling of the treated soils. Monitoring at both sites indicated that liquefiable silts were successfully desaturated. The persistence of desaturation was monitored for 8 months post-treatment at one site and is ongoing at the other site. The monitoring data indicate that the induced desaturation has persisted through seasonal fluctuations of the ground water table since the end of treatment. These data, which document MID longevity, are particularly important to establish MID as a viable option for liquefaction mitigation of silty soils that threatens lifelines worldwide.

Original language	English (US)
Title of host publication	Advancing Lifeline Engineering for Community Resilience
Editors	Craig A. Davis, Kent Yu, Ertugrul Taciroglu
Publisher	American Society of Civil Engineers (ASCE)
Pages	101-113
Number of pages	13
ISBN (Electronic)	9780784484449
DOIs	https://doi.org/10.1061/9780784484449.009
State	Published - 2022
Externally published	Yes
Event	Lifelines 2022 Conference: 1971 San Fernando Earthquake and Lifeline Infrastructure - Los Angeles, United States Duration: Jan 31 2022 → Feb 11 2022

Publication series

Name	Lifelines 2022: 1971 San Fernando Earthquake and Lifeline Infrastructure - Selected Papers from the Lifelines 2022 Conference
Volume	2

Conference

Conference	Lifelines 2022 Conference: 1971 San Fernando Earthquake and Lifeline Infrastructure
Country/Territory	United States
City	Los Angeles
Period	1/31/22 → 2/11/22

ASJC Scopus subject areas

Geotechnical Engineering and Engineering Geology
Civil and Structural Engineering
Mechanical Engineering
Building and Construction

Access to Document

10.1061/9780784484449.009

Cite this

Sorenson, K., Preciado, A. M., Moug, D., Khosravifar, A., Van Paassen, L., Kavazanjian, E., Stokoe, K., & Menq, F. (2022). Field Monitoring of the Persistence of Microbially Induced Desaturation for Mitigation of Earthquake Induced Soil Liquefaction in Silty Soil. In C. A. Davis, K. Yu, & E. Taciroglu (Eds.), Advancing Lifeline Engineering for Community Resilience (pp. 101-113). (Lifelines 2022: 1971 San Fernando Earthquake and Lifeline Infrastructure - Selected Papers from the Lifelines 2022 Conference; Vol. 2). American Society of Civil Engineers (ASCE). https://doi.org/10.1061/9780784484449.009

Field Monitoring of the Persistence of Microbially Induced Desaturation for Mitigation of Earthquake Induced Soil Liquefaction in Silty Soil. / Sorenson, K.; Preciado, A. M.; Moug, D. et al.
Advancing Lifeline Engineering for Community Resilience. ed. / Craig A. Davis; Kent Yu; Ertugrul Taciroglu. American Society of Civil Engineers (ASCE), 2022. p. 101-113 (Lifelines 2022: 1971 San Fernando Earthquake and Lifeline Infrastructure - Selected Papers from the Lifelines 2022 Conference; Vol. 2).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Sorenson, K, Preciado, AM, Moug, D, Khosravifar, A, Van Paassen, L , Kavazanjian, E, Stokoe, K & Menq, F 2022, Field Monitoring of the Persistence of Microbially Induced Desaturation for Mitigation of Earthquake Induced Soil Liquefaction in Silty Soil. in CA Davis, K Yu & E Taciroglu (eds), Advancing Lifeline Engineering for Community Resilience. Lifelines 2022: 1971 San Fernando Earthquake and Lifeline Infrastructure - Selected Papers from the Lifelines 2022 Conference, vol. 2, American Society of Civil Engineers (ASCE), pp. 101-113, Lifelines 2022 Conference: 1971 San Fernando Earthquake and Lifeline Infrastructure, Los Angeles, United States, 1/31/22. https://doi.org/10.1061/9780784484449.009

Sorenson K, Preciado AM, Moug D, Khosravifar A, Van Paassen L , Kavazanjian E et al. Field Monitoring of the Persistence of Microbially Induced Desaturation for Mitigation of Earthquake Induced Soil Liquefaction in Silty Soil. In Davis CA, Yu K, Taciroglu E, editors, Advancing Lifeline Engineering for Community Resilience. American Society of Civil Engineers (ASCE). 2022. p. 101-113. (Lifelines 2022: 1971 San Fernando Earthquake and Lifeline Infrastructure - Selected Papers from the Lifelines 2022 Conference). doi: 10.1061/9780784484449.009

Sorenson, K. ; Preciado, A. M. ; Moug, D. et al. / Field Monitoring of the Persistence of Microbially Induced Desaturation for Mitigation of Earthquake Induced Soil Liquefaction in Silty Soil. Advancing Lifeline Engineering for Community Resilience. editor / Craig A. Davis ; Kent Yu ; Ertugrul Taciroglu. American Society of Civil Engineers (ASCE), 2022. pp. 101-113 (Lifelines 2022: 1971 San Fernando Earthquake and Lifeline Infrastructure - Selected Papers from the Lifelines 2022 Conference).

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abstract = "Earthquake liquefaction hazards in silty soils are a critical problem in Portland, Oregon, and other areas around the world. Recent studies suggest that liquefaction mitigation using microbially induced desaturation (MID) may provide the capability to mitigate liquefaction potential beneath existing structures in a cost-effective manner. The objective of MID is to reduce earthquake-induced excess pore water pressure generation compared to saturated soil, and thereby reduce the potential for triggering liquefaction. A field study of liquefaction mitigation using MID was performed at two sites in Portland in the summer of 2019. Low-plasticity, liquefiable silts were treated with MID by injecting a treatment solution to stimulate native bacteria for a duration of four weeks. This paper presents monitoring data that evaluate the level of desaturation before, during and after the completion of the MID trials. Monitoring included crosshole pressure-wave velocity measurements, a vertical array of embedded sensors that measure water content and bulk electrical conductivity, pre- and post-treatment seismic cone penetration tests, and direct soil sampling of the treated soils. Monitoring at both sites indicated that liquefiable silts were successfully desaturated. The persistence of desaturation was monitored for 8 months post-treatment at one site and is ongoing at the other site. The monitoring data indicate that the induced desaturation has persisted through seasonal fluctuations of the ground water table since the end of treatment. These data, which document MID longevity, are particularly important to establish MID as a viable option for liquefaction mitigation of silty soils that threatens lifelines worldwide.",

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Field Monitoring of the Persistence of Microbially Induced Desaturation for Mitigation of Earthquake Induced Soil Liquefaction in Silty Soil

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