Litcius/Paper detail

Surface‐Volume Scaling Controlled by Dissolution Regimes in a Multiphase Flow Environment

Chen‐Xing Zhou, Ran Hu, Hang Deng, Bowen Ling, Zhibing Yang, Yi‐Feng Chen

2023Geophysical Research Letters27 citationsDOIOpen Access PDF

Abstract

Abstract Fluid‐rock dissolution occurs ubiquitously in geological systems. Surface‐volume scaling is central to predicting overall dissolution rate R involved in modeling dissolution processes. Previous works focused on single‐phase environments but overlooked the multiphase‐flow effect. Here, through limestone‐based microfluidics experiments, we establish a fundamental link between dissolution regimes and scaling laws. In regime I (uniform), the scaling is consistent with classic law, and a satisfactory prediction of R can be obtained. However, the scaling for regime II (localized) deviates significantly from classic law. The underlying mechanism is that the reaction‐induced gas phase forms a layer, acting as a barrier that hinders contact between the acid and rock. Consequently, the error between measurement and prediction continuously amplifies as dissolution proceeds; the predictability is poor. We propose a theoretical model that describes the regime transition, exhibiting excellent agreement with experimental results. This work offers guidance on the usage of scaling law in multiphase flow environments.

Topics & Concepts

DissolutionScalingPredictabilityMultiphase flowFlow (mathematics)Work (physics)Scaling lawPhase (matter)Volume (thermodynamics)MechanicsGeologyVolumetric flow rateMaterials scienceThermodynamicsPhysicsChemistryGeometryMathematicsPhysical chemistryQuantum mechanicsGroundwater flow and contamination studiesCO2 Sequestration and Geologic InteractionsEnhanced Oil Recovery Techniques