Microscale Visualization of Microbial-Induced Calcium Carbonate Precipitation Processes

AbstractMicrobial-induced calcium carbonate (CaCO3) precipitation (MICP) has been explored for its potential engineering applications such as soil stabilization, but current understanding of the fundamental MICP processes at the microscale is limited. In this study, real-time in situ microscale expe...

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Bibliographic Details
Published in:Journal of geotechnical and geoenvironmental engineering 2019-09, Vol.145 (9)
Main Authors: Wang, Yuze, Soga, Kenichi, DeJong, Jason T, Kabla, Alexandre J
Format: Article
Language:English
Subjects:
Calcium
Calcium carbonate
Calcium carbonates
Carbonates
Cementation
Chemical precipitation
Computer simulation
Crystal growth
Crystals
Injection
Microfluidics
Microorganisms
Phase transitions
Porous media
Precipitates
Properties
Soil
Soil porosity
Soil stabilization
Sustainability
Technical Papers
Time dependence
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Summary:AbstractMicrobial-induced calcium carbonate (CaCO3) precipitation (MICP) has been explored for its potential engineering applications such as soil stabilization, but current understanding of the fundamental MICP processes at the microscale is limited. In this study, real-time in situ microscale experiments were conducted using glass slides and microfluidic chips (synthetic porous media that simulate soil matrices to model the conditions similar to actual MICP treatments) to visualize the CaCO3 precipitation process. The results of this study show that irregularly shaped CaCO3 precipitates initially emerged on bacterial aggregates and subsequently dissolved with time as regularly shaped CaCO3 crystals started growing; less stable and smaller CaCO3 crystals may dissolve at the expense of growth of more stable and larger CaCO3 crystals. The time-dependent phase transformation of CaCO3 precipitates makes the size of the crystals formed during MICP highly dependent on the time interval between cementation solution injections during a staged-injection procedure. When the injection interval was 3–5 h, a larger number of crystals (200–1,000 per 106  μm3) with smaller sizes (5–10 μm) was produced. When the injection interval was longer (23–25 h), the crystals were larger (10–80 μm) and fewer in number (5–20 per 106  μm3). The direct observation of MICP processes in this study improves the understanding of MICP fundamentals and the effect of MICP processes on the properties of CaCO3 crystals formed after MICP treatment. These observations will therefore be useful for designing future MICP treatment protocols that improve the properties and sustainability of MICP-treated samples.
ISSN:1090-0241
1943-5606
DOI:10.1061/(ASCE)GT.1943-5606.0002079