Modelling Microbially Induced Carbonate Precipitation (MICP) in Microfluidic Porous Chips

Abstract

Microfluidics is a new experimental approach that investigates the processes related to fluids flowing through small channels or porous media. Microfluidic chips, the core elements of the microfluidic technique, consist of quasi-2-dimensional pore structures etched and sealed in transparent materials. Fluids are allowed to flow through the chips, and real-time observations can be made about the transport and reactions of fluids at the pore scale. In this study, we test the feasibility of using the microfluidic technique to visualise the microbially induced carbonate precipitation (MICP) process. The experimental results obtained in this study show that the generation, evolution, and morphology of calcium carbonate, the effective product in MICP, can be clearly observed during the entire spatial and temporal range of the tests. Comparative tests with different testing variables, including the concentration of treatment solutions, activity of bacterial suspensions, and particle size, were also carried out. The results show that the influence of these variables on the treatment effects, such as the production rate of the reaction, spatial distribution of calcium carbonate, type and morphology of crystals, amount of ammonia gas produced, and presence/absence of clogging issues, can be visualised in microfluidic chips. The results presented in this paper prove that the microfluidic technique could be a helpful tool for unravelling the mechanisms of the MICP process at the pore scale and understanding the factors influencing the MICP process.