Litcius/Paper detail

Homogenization of Dissolution and Enhanced Precipitation Induced by Bubbles in Multiphase Flow Systems

Joaquín Jiménez‐Martínez, Jeffrey D. Hyman, Yu Chen, J. William Carey, Mark L. Porter, Qinjun Kang, George Guthrie, Hari Viswanathan

2020Geophysical Research Letters48 citationsDOIOpen Access PDF

Abstract

Abstract Multiphase flow is ubiquitous in subsurface energy applications and natural processes, such as oil recovery, CO 2 sequestration, and water flow in soils. Despite its importance, we still lack a thorough understanding of the coupling of multiphase flow and reaction of transported fluids with the confining media, including rock dissolution and mineral precipitation. Through the use of geomaterial microfluidic flow experiments and high‐performance computer simulations, we identify key pore‐scale mechanisms that control this coupling. We compare the reactivity of fractured limestone with CO 2 ‐saturated brine (single phase) and a mixture of supercritical (sc) CO 2 and CO 2 ‐saturated brine (multiphase). We find that the presence of scCO 2 bubbles significantly changes both the flow dynamics and the resulting reaction patterns from a single‐phase system, spatially homogenizing the rock dissolution. In addition, bubbles redirect oversaturated fluid into low‐velocity regions, thereby enhancing carbonate precipitation occurs.

Topics & Concepts

DissolutionSupercritical fluidMultiphase flowHomogenization (climate)CarbonateBrinePrecipitationPermeability (electromagnetism)GeologyEnhanced oil recoveryMaterials scienceChemical engineeringMineralogyPetroleum engineeringThermodynamicsChemistryMeteorologyMetallurgyEcologyBiochemistryBiodiversityPhysicsEngineeringBiologyMembraneEnhanced Oil Recovery TechniquesCO2 Sequestration and Geologic InteractionsHydraulic Fracturing and Reservoir Analysis
Homogenization of Dissolution and Enhanced Precipitation Induced by Bubbles in Multiphase Flow Systems | Litcius