Preparation, characterization, and formation mechanism of different biological calcium carbonate (CaCO3) induced by Bacillus mucilaginosus and Bacillus alcalophilus

Microbial-induced calcium carbonate precipitation (MICP) is a common mineralization phenomenon in nature, which has the advantages of green and environmental protection. In this paper, Bacillus mucilaginosus and Bacillus alcalophilus were selected to study the dynamic process of MICP in alkaline solution through the changes of Ca²⁺ concentration, pH value, calcification rate, and Zeta potential, and then the control factors affecting the generation of biological CaCO₃ were revealed. Subsequently, various characterization methods were used to explore the effects of different microbial species on the morphology, crystal polymorph, crystalline size, reflectivity, specific surface area, pore volume, and porosity of biological CaCO₃, and the formation mechanism of biological CaCO₃ was also analyzed carefully. The experimental results showed that microbial mineralization was the control step affecting the formation of biological CaCO₃. Due to the different microbial mineralization mechanisms, the properties of biological CaCO₃ were also different. Compared with the reference CaCO₃, the CaCO₃ induced by Bacillus mucilaginosus was mainly calcite with uniformly dispersed oblique hexahedron shape, while the CaCO₃ induced by Bacillus alcalophilus was mainly vaterite with uniform spherical shape. Meanwhile, the mechanism of MICP showed that Bacillus mucilaginosus mainly promoted the production of biological CaCO₃ through the microbial enzymatic action (carbonic anhydrase), while Bacillus alcalophilus mainly controlled CaCO₃ precipitation through the microbial metabolic decomposition. Generally, the paper reveals the diversity of biomineralization by studying the properties and mechanisms of CaCO₃ induced by different microbial species, which provides the theoretical basis for the application of MICP.