Generic tool for numerical simulation of transformation-diffusion processes in complex volume geometric shapes: application to microbial decomposition of organic matter
This work provides a more efficient tool for researchers simulating microbial decomposition in porous systems, though it is incremental as it builds on prior methods.
The paper tackles the problem of simulating transformation-diffusion processes in complex geometric shapes by generalizing and improving the MOSAIC method, resulting in a more efficient numerical scheme that reduces computational time from several hours or weeks to 10-15 minutes while maintaining similar accuracy compared to classical methods.
This paper presents a generic framework for the numerical simulation of transformation-diffusion processes in complex volume geometric shapes. This work follows a previous one devoted to the simulation of microbial degradation of organic matter in porous system at microscopic scale. We generalized and improved the MOSAIC method significantly and thus yielding a much more generic and efficient numerical simulation scheme. In particular, regarding the simulation of diffusion processes from the graph, in this study we proposed a completely explicit and semi-implicit numerical scheme that can significantly reduce the computational complexity. We validated our method by comparing the results to the one provided by classical Lattice Boltzmann Method (LBM) within the context of microbial decomposition simulation. For the same datasets, we obtained similar results in a significantly shorter computing time (i.e., 10-15 minutes) than the prior work (several hours). Besides the classical LBM method takes around 3 weeks computing time.