Litcius/Paper detail

Exploring Carbonate Rock Dissolution Dynamics and the Influence of Rock Mineralogy in CO<sub>2</sub> Injection

Javad Shokri, Matthias Ruf, Dongwon Lee, Saleh Mohammadrezaei, Holger Steeb, Vahid Niasar

2024Environmental Science & Technology27 citationsDOIOpen Access PDF

Abstract

storage. Accurate estimation of reaction rates enhances predictive modeling in geochemical-flow simulations. Fractured porous media, with distinct transport time scales in fractures and the matrix, raise questions about fracture-matrix interface dissolution rates compared to bulk dissolution rate and the scale-dependency of reaction rate averaging. Our investigation delves into these factors, studying the impact of flow rate and mineralogy on interface dissolution patterns. By injecting carbonated water into carbonate rock samples containing a central channel (mimicking fracture hydrodynamics), our study utilized μCT X-ray imaging at 3.3 μm spatial resolution to estimate the reaction rate and capture the change in pore morphology. Results revealed dissolution rates significantly lower (up to 4 orders of magnitude) than batch experiments. Flow rate notably influenced fracture profiles, causing uneven enlargement at low rates and uniform widening at higher ones. Ankerite presence led to a dissolution-altered layer on the fracture surface, showing high permeability and porosity without greatly affecting the dissolution rate, unlike clay-rich carbonates. This research sheds light on controlling factors influencing dissolution in subsurface environments, critical for accurate modeling in diverse applications.

Topics & Concepts

DissolutionCarbonateMineralogyPorosityGeologyPermeability (electromagnetism)Fracture (geology)Reaction rateVolumetric flow rateAnkeriteCalciteMaterials scienceChemical engineeringChemistryGeotechnical engineeringThermodynamicsMetallurgySideriteEngineeringMembranePhysicsBiochemistryCatalysisCO2 Sequestration and Geologic InteractionsEnhanced Oil Recovery TechniquesGroundwater flow and contamination studies