Microbially induced calcite precipitation performance of multiple landfill indigenous bacteria compared to a commercially available bacteria in porous media

Microbially Induced Carbonate Precipitation (MICP) is currently viewed as one of the potential prominent processes for field applications towards the prevention of soil erosion, healing cracks in bricks, and groundwater contamination. Typically, the bacteria involved in MICP manipulate their environ...

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Published inPloS one Vol. 16; no. 7; p. e0254676
Main Authors Rajasekar, Adharsh, Moy, Charles K. S, Wilkinson, Stephen, Sekar, Raju
Format Journal Article
LanguageEnglish
Published San Francisco Public Library of Science 16.07.2021
Public Library of Science (PLoS)
Subjects
Analysis
Bacillus megaterium
Bacteria
Biology and Life Sciences
Calcite
Calcium carbonate
Calcium permeability
Cell culture
Chemical precipitation
Civil engineering
Columns (structural)
Compressive strength
Crystals
Earth Sciences
Environmental conditions
Experiments
Groundwater
Groundwater pollution
Landfill
Landfills
Leachates
Medicine and Health Sciences
Microorganisms
Permeability
Physical Sciences
Polyvinyl chloride
Porous media
Potential fields
Precipitation
Precipitation (Chemistry)
Reduction
Sand
Sanitary landfills
Shear strength
Soil compaction
Soil contamination
Soil erosion
Soil permeability
Urease
Waste disposal sites
China
United Arab Emirates
Dubai United Arab Emirates
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Summary:Microbially Induced Carbonate Precipitation (MICP) is currently viewed as one of the potential prominent processes for field applications towards the prevention of soil erosion, healing cracks in bricks, and groundwater contamination. Typically, the bacteria involved in MICP manipulate their environment leading to calcite precipitation with an enzyme such as urease, causing calcite crystals to form on the surface of grains forming cementation bonds between particles that help in reducing soil permeability and increase overall compressive strength. In this paper, the main focus is to study the MICP performance of three indigenous landfill bacteria against a well-known commercially bought MICP bacteria (Bacillus megaterium) using sand columns. In order to check the viability of the method for potential field conditions, the tests were carried out at slightly less favourable environmental conditions, i.e., at temperatures between 15-17°C and without the addition of urease enzymes. Furthermore, the sand was loose without any compaction to imitate real ground conditions. The results showed that the indigenous bacteria yielded similar permeability reduction (4.79 E-05 to 5.65 E-05) and calcium carbonate formation (14.4-14.7%) to the control bacteria (Bacillus megaterium), which had permeability reduction of 4.56 E-5 and CaCO.sub.3 of 13.6%. Also, reasonably good unconfined compressive strengths (160-258 kPa) were noted for the indigenous bacteria samples (160 kPa). SEM and XRD showed the variation of biocrystals formation mainly detected as Calcite and Vaterite. Overall, all of the indigenous bacteria performed slightly better than the control bacteria in strength, permeability, and CaCO.sub.3 precipitation. In retrospect, this study provides clear evidence that the indigenous bacteria in such environments can provide similar calcite precipitation potential as well-documented bacteria from cell culture banks. Hence, the idea of MICP field application through biostimulation of indigenous bacteria rather than bioaugmentation can become a reality in the near future.
Bibliography:Competing Interests: The authors have declared that no competing interests exist.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0254676