References
- Achal V, Pan X. 2014. Influence of calcium sources on microbially induced calcium carbonate precipitation by Bacillus sp. CR2. Appl Biochem Biotechnol 173(1):307–317.
- Anbu P, Kang C-H, Shin Y-J, So J-S. 2016. Formations of calcium carbonate minerals by bacteria and its multiple applications. Springerplus 5(1):250.
- Bhaduri S, Debnath N, Mitra S, Liu Y, Kumar A. 2016. Microbiologically induced calcite precipitation mediated by Sporosarcina pasteurii. J Vis Exp 110:20161–20167.
- Chaparro-Acuña SP, Becerra-Jiménez ML, Martínez-Zambrano JJ, Rojas-Sarmiento HA. 2018. Soil bacteria that precipitate calcium carbonate: mechanism and applications of the process. Acta Agron 67(2):277–288.
- Chuo SC, Mohamed SF, Setapar SHM, Ahmad A, Jawaid M, Wani WA, Yaqoob AA, Ibrahim MNM. 2020. Insights into the current trends in the utilization of bacteria for microbially induced calcium carbonate precipitation. Materials 13(21):1–28.
- Dineshbabu G, Uma VS, Mathimani T, Deviram G, Ananth DA, Prabaharan D, Uma L. 2016. On-site concurrent carbon dioxide sequestration from flue gas and calcite formation in ossein effluent by a marine cyanobacterium Phormidium valderianum BDU 20041. Energy Convers Manag 141:315–324.
- Eaton AD, Clesceri LS, Rice EW, Greenberg AE, editors. 2005. Standard Methods of Examination of Water and Wastewater. 21st ed. Washington, DC: American Public Health Association (APHA), p1368.
- Ghorbanzadeh N, Abduolrahimi S, Forghani A, Farhangi MB. 2020. Bioremediation of cadmium in a sandy and a clay soil by microbially induced calcium carbonate precipitation after one week incubation. Arid L Res Manag 34(3):319–335.
- Jalilvand N, Akhgar A, Alikhani HA, Rahmani HA, Rejali F. 2020. Removal of heavy metals zinc, lead, and cadmium by biomineralization of urease-producing bacteria isolated from iranian mine calcareous soils. J Soil Sci Plant Nutr 20(1):206–219.
- Jiang NJ, Liu R, Du YJ, Bi YZ. 2019. Microbial induced carbonate precipitation for immobilizing Pb contaminants: toxic effects on bacterial activity and immobilization efficiency. Sci Total Environ 672:722–731.
- Kang CH, Han SH, Shin Y, Oh SJ, So JS. 2014. Bioremediation of Cd by microbially induced calcite precipitation. Appl Biochem Biotechnol 172(4):1929–1937.
- Kim J-H, Lee J-Y. 2019. An optimum condition of MICP indigenous bacteria with contaminated wastes of heavy metal. J Mater Cycles Waste Manag 21(2):239–247.
- Mahanty B, Kim S, Kim CG. 2013. Assessment of a biostimulated or bioaugmented calcification system with Bacillus pasteurii in a simulated soil environment. Microb Ecol 65(3):679–688.
- Mahanty B, Kim S, Kim CG. 2014. Dissolved inorganic carbon inventory and CO2Sequestration in ureolytic biocalcification process with Bacillus pasteurii. Geomicrobiol J 31(2):145–151.
- Millo C, Dupraz S, Ader M, Guyot F, Thaler C, Foy E, Ménez B. 2012. Carbon isotope fractionation during calcium carbonate precipitation induced by ureolytic bacteria. Geochim Cosmochim Acta 98:107–124.
- Nathan VK, Vijayan J, Parvathi A. 2020. Optimization of urease production by Bacillus halodurans PO15: a mangrove bacterium from Poovar mangroves, India. Mar Life Sci Technol 2(2):194–202.
- Omoregie AI, Ong DEL, Nissom PM. 2019. Assessing ureolytic bacteria with calcifying abilities isolated from limestone caves for biocalcification. Lett Appl Microbiol 68(2):173–181.
- Portugal CRM, Fonyo C, Machado CC, Meganck R, Jarvis T. 2020. Microbiologically Induced Calcite Precipitation biocementation, green alternative for roads – is this the breakthrough? A critical review. J Clean Prod 262:121372. https://doi.org/10.1016/j.jclepro.2020.121372.
- Sarda D, Choonia HS, Sarode DD, Lele SS. 2009. Biocalcification by Bacillus pasteurii urease: a novel application. J Ind Microbiol Biotechnol 36(8):1111–1115.
- Sharma M, Satyam N, Reddy KR. 2019. Investigation of various gram-positive bacteria for MICP in Narmada Sand, India. Int J Geotech Eng 15(2):220–234.
- Tamayo-Figueroa DP, Castillo E, Brandão PFB. 2019. Metal and metalloid immobilization by microbiologically induced carbonates precipitation. World J Microbiol Biotechnol 35(4):58.
- Tamura K, Nei M. 1993. Estimation of the number of nucleotide substitutions in the control region of mitochondrial DNA in humans and chimpanzees. Mol Biol Evol 10(3):512–526.
- Torres-Aravena ÁE, Duarte-Nass C, Azócar L, Mella-Herrera R, Rivas M, Jeison D. 2018. Can microbially induced calcite precipitation (MICP) through a ureolytic pathway be successfully applied for removing heavy metals from wastewaters? Crystals 8(11):438.
- Vashisht R, Attri S, Sharma D, Shukla A, Goel G. 2018. Monitoring biocalcification potential of Lysinibacillus sp. isolated from alluvial soils for improved compressive strength of concrete. Microbiol Res 207:226–231.
- Xenofontos E, Tanase A, Stoica I, Vyrides I. 2016. Newly isolated alkalophilic Advenella species bioaugmented in activated sludge for high p-cresol removal. N Biotechnol 33(2):305–310.
- Yang J, Pan X, Zhao C, Mou S, Achal V, Al-Misned FA, Mortuza MG, Gadd GM. 2016. Bioimmobilization of heavy metals in acidic copper mine tailings soil. Geomicrobiol J 33(3–4):261–266.
- Yu T, Souli H, Péchaud Y, Fleureau J-M. 2020. Optimizing protocols for microbial induced calcite precipitation (MICP) for soil improvement–a review. Eur J Environ Civ Eng.1–16. doi:10.1080/19648189.2020.1755370.
- Zhao Y, Yao J, Yuan Z, Wang T, Zhang Y, Wang F. 2017. Bioremediation of Cd by strain GZ-22 isolated from mine soil based on biosorption and microbially induced carbonate precipitation. Environ Sci Pollut Res Int 24(1):372–380.