Increased Microbially Induced Calcium Carbonate Precipitation (MICP) Efficiency in Multiple Treatment Sand Biocementation Processes by Augmentation of Cementation Medium with Ammonium Chloride

Spencer, Christine Ann; Sass, Henrik; van Paassen, Leon

doi:10.3390/geotechnics3040057

Cited by 3 publications

(6 citation statements)

References 35 publications

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“…This result underscores the efficacy of cementation between sand particles. Notably, similar findings have been reported in previous studies where individual bacteria were employed to improve permeability in the sand (Liu et al 2020 ; Namdar-Khojasteh et al 2022 ; Spencer et al 2023 ; Ugur et al 2024 ). The B2 & B11-30 °C combination yielded the best permeability result with 1.54 × 10 − 6 m/s compared to all the other bacterial samples.…”

Section: Resultssupporting

confidence: 87%

“…Calcite precipitation was assessed using X-ray diffraction (XRD) analysis to identify mineral phases and scanning electron microscopy (SEM) to visualize crystal morphology and distribution. Multiple studies have used these methods to provide insights into the effectiveness of bacterial strains in promoting sand cementation and calcium carbonate precipitation (Spencer et al 2023 ; Zeitouny et al 2023 ). The ability of the bacterial strains to perform in sand was assessed at two different temperatures, 14 ± 0.6 °C and 30 °C.…”

Section: Resultsmentioning

confidence: 99%

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Synergistic biocementation: harnessing Comamonas and Bacillus ureolytic bacteria for enhanced sand stabilization

Rajasekar,

Zhao,

et al. 2024

World J Microbiol Biotechnol

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Biocementation, driven by ureolytic bacteria and their biochemical activities, has evolved as a powerful technology for soil stabilization, crack repair, and bioremediation. Ureolytic bacteria play a crucial role in calcium carbonate precipitation through their enzymatic activity, hydrolyzing urea to produce carbonate ions and elevate pH, thus creating favorable conditions for the precipitation of calcium carbonate. While extensive research has explored the ability of ureolytic bacteria isolated from natural environments or culture conditions, bacterial synergy is often unexplored or under-reported. In this study, we isolated bacterial strains from the local eutrophic river canal and evaluated their suitability for precipitating calcium carbonate polymorphs. We identified two distinct bacterial isolates with superior urea degradation ability (conductivity method) using partial 16 S rRNA gene sequencing. Molecular identification revealed that they belong to the Comamonas and Bacillus genera. Urea degradation analysis was performed under diverse pH (6,7 and 8) and temperature (15 °C,20 °C,25 °C and 30 °C) ranges, indicating that their ideal pH is 7 and temperature is 30 °C since 95% of the urea was degraded within 96 h. In addition, we investigated these strains individually and in combination, assessing their microbially induced carbonate precipitation (MICP) in silicate fine sand under low (14 ± 0.6 °C) and ideal temperature 30 °C conditions, aiming to optimize bio-mediated soil enhancement. Results indicated that 30 °C was the ideal temperature, and combining bacteria resulted in significant (p ≤ 0.001) superior carbonate precipitation (14–16%) and permeability (> 10− 6 m/s) in comparison to the average range of individual strains. These findings provide valuable insights into the potential of combining ureolytic bacteria for future MICP research on field applications including soil erosion mitigation, soil stabilization, ground improvement, and heavy metal remediation.

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Section: Resultssupporting

confidence: 87%

Section: Resultsmentioning

confidence: 99%

Synergistic biocementation: harnessing Comamonas and Bacillus ureolytic bacteria for enhanced sand stabilization

Rajasekar,

Zhao,

et al. 2024

World J Microbiol Biotechnol

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“…Thus, in order to perform a comparison between different techniques, different studies with relatively similar soil types and compaction levels were used, whose results are presented in Table 5. As can be seen, ureolytic MICP technique [50] has resulted in an almost similar UCS range. Spencer et al [50] enhanced ureolytic MICP performance by adding ammonium chloride to increase the urease reaction efficiency, which has augmented the unconfined compressive strength.…”

Section: Ureolytic and Non-ureolytic Micp Versus Other Additives: Imp...mentioning

confidence: 68%

“…Spencer et al. [50] enhanced ureolytic MICP performance by adding ammonium chloride to increase the urease reaction efficiency, which has augmented the unconfined compressive strength. However, both ureolytic MICP and its augmented version suffer from production of ammonium ions, which are absent in the non‐ureolytic MICP.…”

Section: Ureolytic and Non‐ureolytic Micp Versus Other Additives: Imp...mentioning

confidence: 99%

Section: Ureolytic and Non‐ureolytic Micp Versus Other Additives: Imp...mentioning

confidence: 99%

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Non‐ureolytic microbially induced carbonate precipitation: Investigating a cleaner biogeotechnical engineering pathway for soil mechanical improvement

Hemayati,

Nematollahi,

Nikooee

et al. 2024

The Journal of Engineering

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As the world's population grows, there is an increasing need for soil improvement techniques to accommodate construction demands. Current methods, most often, suffer from a high CO2 footprint, leading researchers to resort to biological methods of soil improvement through microbially induced carbonate precipitation (MICP). Commonly used ureolytic microbial carbonate precipitation produces ammonium ions, which can be environmentally concerning. The present study, therefore, addresses the use of non‐ureolytic MICP for soil improvement. The process of non‐ureolytic MICP relies on the use of heterotrophic bacteria to catalyze the oxidation reaction of organic compounds, eventually calcium carbonate precipitation. In this study, heterotrophic bacteria, such as Bacillus subtilis and Bacillus amyloliquefaciens, have been investigated as a solution for soil improvement via an ammonium‐free MICP. Calcium formate and calcium acetate are used as both calcium and carbon sources. This study, furthermore, examines the impact of MICP treatment on sandy soil and the effect of compaction level on treated samples. The findings indicate that the non‐ureolytic MICP method is an effective approach for stabilizing sand. The Calcium Formate‐B.Subtilis composition is shown to be the most effective compound for improving the unconfined compressive strength of sandy soils, while the Calcium Acetate‐B.Amyloliquefaciens composition is the least effective.

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Surface-displayed silicatein-α enzyme in bioengineered E. coli enables biocementation and silica mineralization

Vigil,

Schwendeman,

Grogger

et al. 2024

Front. Syst. Biol.

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Biocementation is an exciting biomanufacturing alternative to common cement, which is a significant contributor of CO2 greenhouse gas production. In nature biocementation processes are usually modulated via ureolytic microbes, such as Sporosarcina pasteurii, precipitating calcium carbonate to cement particles together, but these ureolytic reactions also produce ammonium and carbonate byproducts, which may have detrimental effects on the environment. As an alternative approach, this work examines biosilicification via surface-displayed silicatein-α in bio-engineered E. coli as an in vivo biocementation strategy. The surface-display of silicatein-α with ice nucleation protein is a novel protein fusion combination that effectively enables biosilicification, which is the polymerization of silica species in solution, from the surface of E. coli bacterial cells. Biosilicification with silicatein-α produces biocementation products with comparable compressive strength as S. pasteurii. This biosilicification approach takes advantage of the high silica content found naturally in sand and does not produce the ammonium and carbonate byproducts of ureolytic bacteria, making this a more environmentally friendly biocementation strategy.

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Increased Microbially Induced Calcium Carbonate Precipitation (MICP) Efficiency in Multiple Treatment Sand Biocementation Processes by Augmentation of Cementation Medium with Ammonium Chloride

Cited by 3 publications

References 35 publications

Synergistic biocementation: harnessing Comamonas and Bacillus ureolytic bacteria for enhanced sand stabilization

Synergistic biocementation: harnessing Comamonas and Bacillus ureolytic bacteria for enhanced sand stabilization

Non‐ureolytic microbially induced carbonate precipitation: Investigating a cleaner biogeotechnical engineering pathway for soil mechanical improvement

Surface-displayed silicatein-α enzyme in bioengineered E. coli enables biocementation and silica mineralization

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