Bio-cementation of sand using enzyme-induced calcite precipitation: Mechanical behavior and microstructural analysis

The enzyme-induced calcite precipitation (EICP) has recently gained popularity as a ground improvement technique. Bio-cementation via EICP increases the strength, stiffness, and soil liquefaction resistance by clogging the voids and binding the soil particles with calcium carbonate. The objectives o...

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Published in:Construction & building materials Vol. 417; p. 135360
Main Authors: Gitanjali, Amali, Jhuo, Yu-Syuan, Yeh, Fu-Hsuan, Ge, Louis
Format: Journal Article
Language:English
Published: Elsevier Ltd 23.02.2024
Subjects:
Bio-cementation
Calcium carbonate (CaCO3)/Calcite
Consolidated drained triaxial test
Cyclic triaxial test
Enzyme-induced calcite precipitation (EICP)
Liquefaction
Enzyme-induced calcite precipitation (EICP)
Cyclic triaxial test
Bio-cementation
Liquefaction
Calcium carbonate (CaCO3)/Calcite
Consolidated drained triaxial test
ISSN:0950-0618, 1879-0526
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Abstract The enzyme-induced calcite precipitation (EICP) has recently gained popularity as a ground improvement technique. Bio-cementation via EICP increases the strength, stiffness, and soil liquefaction resistance by clogging the voids and binding the soil particles with calcium carbonate. The objectives of the study involve assessing the mechanical behavior of the EICP-treated sand by performing monotonic consolidated drained triaxial and undrained cyclic triaxial tests. This study adopted a one-phase EICP cementation solution consisting of 1 M Urea, 0.67 M Calcium chloride dihydrate, and 3 g/l urease enzyme. The monotonic triaxial tests on pure sand and EICP-treated sand with 3,7, and 14 curing days were carried out at 50, 100, and 200 kPa confining pressures, respectively. A noticeable effective cohesion was observed for EICP-treated sand for all curing durations. Undrained cyclic triaxial tests on the EICP-treated specimens with 7 days of curing were performed at an effective confining pressure of 100 kPa. As expected, the number of cycles to liquefaction was higher in the EICP-treated specimen compared to pure sand due to the cementation effect. Finally, scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS) mapping confirmed the enhanced liquefaction resistance in EICP-treated sand due to calcium carbonate precipitation, leading to particle-to-particle interlocking. Additionally, X-ray Diffraction (XRD) analysis revealed the presence of calcite crystals resulting from the EICP treatment. •A one-phase EICP treatment for sandy specimen preparation was developed.•A noticeable effective cohesion was observed for EICP-treated sand.•SEM and EDS confirmed the liquefaction resistance enhancement.
AbstractList The enzyme-induced calcite precipitation (EICP) has recently gained popularity as a ground improvement technique. Bio-cementation via EICP increases the strength, stiffness, and soil liquefaction resistance by clogging the voids and binding the soil particles with calcium carbonate. The objectives of the study involve assessing the mechanical behavior of the EICP-treated sand by performing monotonic consolidated drained triaxial and undrained cyclic triaxial tests. This study adopted a one-phase EICP cementation solution consisting of 1 M Urea, 0.67 M Calcium chloride dihydrate, and 3 g/l urease enzyme. The monotonic triaxial tests on pure sand and EICP-treated sand with 3,7, and 14 curing days were carried out at 50, 100, and 200 kPa confining pressures, respectively. A noticeable effective cohesion was observed for EICP-treated sand for all curing durations. Undrained cyclic triaxial tests on the EICP-treated specimens with 7 days of curing were performed at an effective confining pressure of 100 kPa. As expected, the number of cycles to liquefaction was higher in the EICP-treated specimen compared to pure sand due to the cementation effect. Finally, scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS) mapping confirmed the enhanced liquefaction resistance in EICP-treated sand due to calcium carbonate precipitation, leading to particle-to-particle interlocking. Additionally, X-ray Diffraction (XRD) analysis revealed the presence of calcite crystals resulting from the EICP treatment. •A one-phase EICP treatment for sandy specimen preparation was developed.•A noticeable effective cohesion was observed for EICP-treated sand.•SEM and EDS confirmed the liquefaction resistance enhancement.
ArticleNumber 135360
Author Yeh, Fu-Hsuan
Gitanjali, Amali
Jhuo, Yu-Syuan
Ge, Louis
Author_xml – sequence: 1
  givenname: Amali
  surname: Gitanjali
  fullname: Gitanjali, Amali
  organization: Department of Civil Engineering, National Taiwan University, Taiwan
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  givenname: Yu-Syuan
  orcidid: 0000-0002-7907-4314
  surname: Jhuo
  fullname: Jhuo, Yu-Syuan
  organization: Department of Civil Engineering, National Taiwan University, Taiwan
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  givenname: Fu-Hsuan
  surname: Yeh
  fullname: Yeh, Fu-Hsuan
  organization: Department of Civil and Construction Engineering, National Taiwan University of Science and Technology, Taiwan
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  givenname: Louis
  orcidid: 0000-0002-1150-3733
  surname: Ge
  fullname: Ge, Louis
  email: louisge@ntu.edu.tw
  organization: Department of Civil Engineering, National Taiwan University, Taiwan
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Keywords Enzyme-induced calcite precipitation (EICP)
Cyclic triaxial test
Bio-cementation
Liquefaction
Calcium carbonate (CaCO3)/Calcite
Consolidated drained triaxial test
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Snippet The enzyme-induced calcite precipitation (EICP) has recently gained popularity as a ground improvement technique. Bio-cementation via EICP increases the...
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SubjectTerms Bio-cementation
Calcium carbonate (CaCO3)/Calcite
Consolidated drained triaxial test
Cyclic triaxial test
Enzyme-induced calcite precipitation (EICP)
Liquefaction
Title Bio-cementation of sand using enzyme-induced calcite precipitation: Mechanical behavior and microstructural analysis
URI https://dx.doi.org/10.1016/j.conbuildmat.2024.135360
Volume 417
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