Dynamic response of liquefiable sand improved by microbial-induced calcite precipitation
Microbial-induced calcite precipitation (MICP), a novel bio-mediated ground improvement method, was explored to mitigate liquefaction-prone soils. Geotechnical centrifuge tests were used to evaluate cementation integrity and the response of MICP cemented sands to dynamic loading. The cementation int...
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| Veröffentlicht in: | Géotechnique 2013-03, Vol.63 (4), p.302-312 |
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| creator | MONTOYA, B. M DEJONG, J. T BOULANGER, R. W |
| description | Microbial-induced calcite precipitation (MICP), a novel bio-mediated ground improvement method, was explored to mitigate liquefaction-prone soils. Geotechnical centrifuge tests were used to evaluate cementation integrity and the response of MICP cemented sands to dynamic loading. The cementation integrity testing reveals a change in behaviour from 'soil like' to 'rock like', with an increase in treatment level. Results from dynamic testing demonstrate a clear increase in resistance to liquefaction of MICP-treated sands compared to untreated loose sand. The MICP sands were treated to varying levels of cementation (light, moderate and heavy cementation levels) and assessed using nondestructive shear wave velocity measurements. The centrifuge models were all subjected to ground motions consisting of sine waves with increasing amplitudes. Accelerations, pore pressures and settlements were measured in the soil during shaking, and the changes in soil behaviour and postshaking shear wave velocity for soils prepared to different cementation levels are discussed. Increased resistance to liquefaction was demonstrated with a decrease in excess pore pressure ratios in the MICP-treated models, as well as in reduced post-shaking settlements; however, surface accelerations were amplified at heavy levels of cementation. A tradeoffbetween improving liquefaction resistance and minimising undesirable higher surface accelerations needs to be considered when designing the soil improvement level. |
| doi_str_mv | 10.1680/geot.sip13.p.019 |
| format | Article |
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M ; DEJONG, J. T ; BOULANGER, R. W</creator><creatorcontrib>MONTOYA, B. M ; DEJONG, J. T ; BOULANGER, R. W</creatorcontrib><description>Microbial-induced calcite precipitation (MICP), a novel bio-mediated ground improvement method, was explored to mitigate liquefaction-prone soils. Geotechnical centrifuge tests were used to evaluate cementation integrity and the response of MICP cemented sands to dynamic loading. The cementation integrity testing reveals a change in behaviour from 'soil like' to 'rock like', with an increase in treatment level. Results from dynamic testing demonstrate a clear increase in resistance to liquefaction of MICP-treated sands compared to untreated loose sand. The MICP sands were treated to varying levels of cementation (light, moderate and heavy cementation levels) and assessed using nondestructive shear wave velocity measurements. The centrifuge models were all subjected to ground motions consisting of sine waves with increasing amplitudes. Accelerations, pore pressures and settlements were measured in the soil during shaking, and the changes in soil behaviour and postshaking shear wave velocity for soils prepared to different cementation levels are discussed. Increased resistance to liquefaction was demonstrated with a decrease in excess pore pressure ratios in the MICP-treated models, as well as in reduced post-shaking settlements; however, surface accelerations were amplified at heavy levels of cementation. 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The centrifuge models were all subjected to ground motions consisting of sine waves with increasing amplitudes. Accelerations, pore pressures and settlements were measured in the soil during shaking, and the changes in soil behaviour and postshaking shear wave velocity for soils prepared to different cementation levels are discussed. Increased resistance to liquefaction was demonstrated with a decrease in excess pore pressure ratios in the MICP-treated models, as well as in reduced post-shaking settlements; however, surface accelerations were amplified at heavy levels of cementation. 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M</au><au>DEJONG, J. T</au><au>BOULANGER, R. W</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Dynamic response of liquefiable sand improved by microbial-induced calcite precipitation</atitle><jtitle>Géotechnique</jtitle><date>2013-03-01</date><risdate>2013</risdate><volume>63</volume><issue>4</issue><spage>302</spage><epage>312</epage><pages>302-312</pages><issn>0016-8505</issn><eissn>1751-7656</eissn><coden>GTNQA8</coden><abstract>Microbial-induced calcite precipitation (MICP), a novel bio-mediated ground improvement method, was explored to mitigate liquefaction-prone soils. Geotechnical centrifuge tests were used to evaluate cementation integrity and the response of MICP cemented sands to dynamic loading. The cementation integrity testing reveals a change in behaviour from 'soil like' to 'rock like', with an increase in treatment level. Results from dynamic testing demonstrate a clear increase in resistance to liquefaction of MICP-treated sands compared to untreated loose sand. The MICP sands were treated to varying levels of cementation (light, moderate and heavy cementation levels) and assessed using nondestructive shear wave velocity measurements. The centrifuge models were all subjected to ground motions consisting of sine waves with increasing amplitudes. Accelerations, pore pressures and settlements were measured in the soil during shaking, and the changes in soil behaviour and postshaking shear wave velocity for soils prepared to different cementation levels are discussed. Increased resistance to liquefaction was demonstrated with a decrease in excess pore pressure ratios in the MICP-treated models, as well as in reduced post-shaking settlements; however, surface accelerations were amplified at heavy levels of cementation. 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| subjects | Acceleration Applied geophysics Behavior Calcite Cementation Centrifuges Chemical reactions Earth sciences Earth, ocean, space Engineering and environment geology. Geothermics Engineering geology Exact sciences and technology Ground motion Internal geophysics Liquefaction Methods Microorganisms Pore pressure Sand Sand & gravel Settlements Shear strength Soils Studies Wave velocity |
| title | Dynamic response of liquefiable sand improved by microbial-induced calcite precipitation |
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