Abstract
One important unresolved question in reactive transport is how pore-scale processes can be upscaled and how predictions can be made on the mutual effect of chemical processes and fluid flow in the porous medium. It is paramount to predict the location of mineral precipitation besides their amount for understanding the fate of transport properties. However, current models and simulation approaches fail to predict precisely where crystals will nucleate and grow in the spatiotemporal domain. We present a new mathematical model for probabilistic mineral nucleation and precipitation. A Lattice Boltzmann implementation of the two-dimensional mineral surface was developed to evaluate geometry evolution when probabilistic nucleation criterion is incorporated. To provide high-resolution surface information on mineral precipitation, growth, and distribution, we conducted a total of 27 calcium carbonate synthesis experiments in the laboratory. The results indicate that nucleation events as precursors determine the location and timing of crystal precipitation. It is shown that reaction rate has primary control over covering the substrate with nuclei and, subsequently, solid-phase accumulation. The work provides insight into the spatiotemporal evolution of porous media by suggesting probabilistic and deterministic domains for studying reactive transport processes. We indicate in which length- and time-scales it is essential to incorporate probabilistic nucleation for valid predictions.
Highlights
One important unresolved question in reactive transport is how pore-scale processes can be upscaled and how predictions can be made on the mutual effect of chemical processes and fluid flow in the porous medium
Fluid flow, rock deformation, and chemical reactions resulting from temperature and pressure gradients, geomechanical stresses, and chemical disequilibria are manifested in coupled thermo-hydro-mechanicalchemical (THMC) processes governing the long-term behavior of the fluid-rock system in geo-environments[1,2]
The reactive transport modeling (RTM) framework must satisfy the specific system of interest, ranging from advective–diffusive transport of solutes close to a mineral surface[10,13,16,29,30] to fluid flow and reactions at the field- or regional-scales and over geological time[11,31,32,33]
Summary
One important unresolved question in reactive transport is how pore-scale processes can be upscaled and how predictions can be made on the mutual effect of chemical processes and fluid flow in the porous medium. Mineral nucleation is a probabilistic process where crystals nucleate anywhere given similar conditions such as surface properties, supersaturation, and temperature. As a pore-scale realization of probabilistic nucleation, we developed a Lattice Boltzmann Method (LBM) reactive transport model to simulate crystal nucleation and precipitation on a two-dimensional mineral surface substrate.
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