Field Trials of Microbially Induced Desaturation in Low-Plasticity Silt

Diane M. Moug; Kayla R. Sorenson; Arash Khosravifar; Melissa Preciado; Elizabeth Stallings Young; Leon Van Paassen; Edward Kavazanjian; Benchen Zhang; Kenneth H. Stokoe; Farnyuh M. Menq; Yumei Wang

doi:10.1061/(ASCE)GT.1943-5606.0002890

Field Trials of Microbially Induced Desaturation in Low-Plasticity Silt

Diane M. Moug, Kayla R. Sorenson, Arash Khosravifar, Melissa Preciado, Elizabeth Stallings Young, Leon Van Paassen, Edward Kavazanjian, Benchen Zhang, Kenneth H. Stokoe, Farnyuh M. Menq, Yumei Wang

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

Field trials of microbially induced desaturation (MID) were conducted at two sites in Portland, Oregon underlain by liquefiable fine-grained soils. MID is an emerging method for mitigating the potential for triggering liquefaction. MID treatment stimulates native denitrifying microbes with a solution containing nitrate, as well as other substrates and nutrients. An end product of the denitrification reactions is nitrogen gas, which displaces soil porewater and in turn reduces the in situ degree of saturation (Sr). Because during cyclic loading desaturated soils produce less excess porewater pressure than saturated soils, MID can mitigate the potential for triggering liquefaction. Monitoring for the two field trials was performed to evaluate the MID treatment performance and the associated subsurface desaturation. Monitoring data included seismic wave velocities measured with crosshole and downhole techniques, embedded in situ moisture and electrical conductivity sensors, water chemistry measurements, and recovery and testing of samples for changes in soil properties. Monitoring data were collected pretreatment, during treatment, and post-treatment, and then interpreted to evaluate the effectiveness of MID for reducing Sr in fine grained, low plasticity silts in the two distinct sites. Despite geotechnical site characterization data that show the field trial sites have distinct geotechnical characteristics, including interbedding, that affect liquefaction susceptibility and MID treatment application, results indicate liquefiable soil at both sites was successfully desaturated and that the desaturation persisted for at least 92 days post-treatment.

Original language	English (US)
Article number	05022005
Journal	Journal of Geotechnical and Geoenvironmental Engineering
Volume	148
Issue number	11
DOIs	https://doi.org/10.1061/(ASCE)GT.1943-5606.0002890
State	Published - Nov 1 2022
Externally published	Yes

ASJC Scopus subject areas

Environmental Science(all)
Geotechnical Engineering and Engineering Geology

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10.1061/(ASCE)GT.1943-5606.0002890

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Moug, D. M., Sorenson, K. R., Khosravifar, A., Preciado, M., Stallings Young, E., Van Paassen, L., Kavazanjian, E., Zhang, B., Stokoe, K. H., Menq, F. M., & Wang, Y. (2022). Field Trials of Microbially Induced Desaturation in Low-Plasticity Silt. Journal of Geotechnical and Geoenvironmental Engineering, 148(11), Article 05022005. https://doi.org/10.1061/(ASCE)GT.1943-5606.0002890

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title = "Field Trials of Microbially Induced Desaturation in Low-Plasticity Silt",

abstract = "Field trials of microbially induced desaturation (MID) were conducted at two sites in Portland, Oregon underlain by liquefiable fine-grained soils. MID is an emerging method for mitigating the potential for triggering liquefaction. MID treatment stimulates native denitrifying microbes with a solution containing nitrate, as well as other substrates and nutrients. An end product of the denitrification reactions is nitrogen gas, which displaces soil porewater and in turn reduces the in situ degree of saturation (Sr). Because during cyclic loading desaturated soils produce less excess porewater pressure than saturated soils, MID can mitigate the potential for triggering liquefaction. Monitoring for the two field trials was performed to evaluate the MID treatment performance and the associated subsurface desaturation. Monitoring data included seismic wave velocities measured with crosshole and downhole techniques, embedded in situ moisture and electrical conductivity sensors, water chemistry measurements, and recovery and testing of samples for changes in soil properties. Monitoring data were collected pretreatment, during treatment, and post-treatment, and then interpreted to evaluate the effectiveness of MID for reducing Sr in fine grained, low plasticity silts in the two distinct sites. Despite geotechnical site characterization data that show the field trial sites have distinct geotechnical characteristics, including interbedding, that affect liquefaction susceptibility and MID treatment application, results indicate liquefiable soil at both sites was successfully desaturated and that the desaturation persisted for at least 92 days post-treatment.",

author = "Moug, {Diane M.} and Sorenson, {Kayla R.} and Arash Khosravifar and Melissa Preciado and {Stallings Young}, Elizabeth and {Van Paassen}, Leon and Edward Kavazanjian and Benchen Zhang and Stokoe, {Kenneth H.} and Menq, {Farnyuh M.} and Yumei Wang",

note = "Funding Information: Funding for this research was provided by the NSF (Awards CMMI-1935670 and 1935774). Additional support was provided through the NSF Engineering Research Center for Bio-mediated and Bio-inspired Geotechnics (under NSF Award ERC-1449501) and NSF-supported National Hazards Engineering Research Infrastructure equipment facility at the University of Texas at Austin (under NSF Award CMMI-1520808). Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of the NSF. This work was possible through partnerships with Oregon Department of Geology and Mineral Industries, Condon Johnson & Associates, ConeTec, Portland General Electric, the City of Portland, Portland Bureau of Transportation, Portland Water Bureau, and Geosyntec Consultants. Valuable project support was provided by Melissa Boell and Max Miller through an NSF REU Supplement (under Award CMMI-2006832), and Daniel Stuart. Publisher Copyright: {\textcopyright} 2022 American Society of Civil Engineers.",

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doi = "10.1061/(ASCE)GT.1943-5606.0002890",

language = "English (US)",

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journal = "Journal of Geotechnical and Geoenvironmental Engineering",

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AU - Moug, Diane M.

AU - Sorenson, Kayla R.

AU - Khosravifar, Arash

AU - Preciado, Melissa

AU - Stallings Young, Elizabeth

AU - Van Paassen, Leon

AU - Kavazanjian, Edward

AU - Zhang, Benchen

AU - Stokoe, Kenneth H.

AU - Menq, Farnyuh M.

AU - Wang, Yumei

N1 - Funding Information: Funding for this research was provided by the NSF (Awards CMMI-1935670 and 1935774). Additional support was provided through the NSF Engineering Research Center for Bio-mediated and Bio-inspired Geotechnics (under NSF Award ERC-1449501) and NSF-supported National Hazards Engineering Research Infrastructure equipment facility at the University of Texas at Austin (under NSF Award CMMI-1520808). Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of the NSF. This work was possible through partnerships with Oregon Department of Geology and Mineral Industries, Condon Johnson & Associates, ConeTec, Portland General Electric, the City of Portland, Portland Bureau of Transportation, Portland Water Bureau, and Geosyntec Consultants. Valuable project support was provided by Melissa Boell and Max Miller through an NSF REU Supplement (under Award CMMI-2006832), and Daniel Stuart. Publisher Copyright: © 2022 American Society of Civil Engineers.

PY - 2022/11/1

Y1 - 2022/11/1

N2 - Field trials of microbially induced desaturation (MID) were conducted at two sites in Portland, Oregon underlain by liquefiable fine-grained soils. MID is an emerging method for mitigating the potential for triggering liquefaction. MID treatment stimulates native denitrifying microbes with a solution containing nitrate, as well as other substrates and nutrients. An end product of the denitrification reactions is nitrogen gas, which displaces soil porewater and in turn reduces the in situ degree of saturation (Sr). Because during cyclic loading desaturated soils produce less excess porewater pressure than saturated soils, MID can mitigate the potential for triggering liquefaction. Monitoring for the two field trials was performed to evaluate the MID treatment performance and the associated subsurface desaturation. Monitoring data included seismic wave velocities measured with crosshole and downhole techniques, embedded in situ moisture and electrical conductivity sensors, water chemistry measurements, and recovery and testing of samples for changes in soil properties. Monitoring data were collected pretreatment, during treatment, and post-treatment, and then interpreted to evaluate the effectiveness of MID for reducing Sr in fine grained, low plasticity silts in the two distinct sites. Despite geotechnical site characterization data that show the field trial sites have distinct geotechnical characteristics, including interbedding, that affect liquefaction susceptibility and MID treatment application, results indicate liquefiable soil at both sites was successfully desaturated and that the desaturation persisted for at least 92 days post-treatment.

AB - Field trials of microbially induced desaturation (MID) were conducted at two sites in Portland, Oregon underlain by liquefiable fine-grained soils. MID is an emerging method for mitigating the potential for triggering liquefaction. MID treatment stimulates native denitrifying microbes with a solution containing nitrate, as well as other substrates and nutrients. An end product of the denitrification reactions is nitrogen gas, which displaces soil porewater and in turn reduces the in situ degree of saturation (Sr). Because during cyclic loading desaturated soils produce less excess porewater pressure than saturated soils, MID can mitigate the potential for triggering liquefaction. Monitoring for the two field trials was performed to evaluate the MID treatment performance and the associated subsurface desaturation. Monitoring data included seismic wave velocities measured with crosshole and downhole techniques, embedded in situ moisture and electrical conductivity sensors, water chemistry measurements, and recovery and testing of samples for changes in soil properties. Monitoring data were collected pretreatment, during treatment, and post-treatment, and then interpreted to evaluate the effectiveness of MID for reducing Sr in fine grained, low plasticity silts in the two distinct sites. Despite geotechnical site characterization data that show the field trial sites have distinct geotechnical characteristics, including interbedding, that affect liquefaction susceptibility and MID treatment application, results indicate liquefiable soil at both sites was successfully desaturated and that the desaturation persisted for at least 92 days post-treatment.

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Field Trials of Microbially Induced Desaturation in Low-Plasticity Silt

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