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Hydrophobic Nanoconfinement Enhances CO <sub>2</sub> Conversion to H <sub>2</sub> CO <sub>3</sub>

Nabankur Dasgupta, Tuan A. Ho, Susan B. Rempe, Yifeng Wang

2023The Journal of Physical Chemistry Letters24 citationsDOIOpen Access PDF

Abstract

Understanding the formation of H 2 CO 3 in water from CO 2 is important in environmental and industrial processes. Although numerous investigations have studied this reaction, the conversion of CO 2 to H 2 CO 3 in nanopores, and how it differs from that in bulk water, has not been understood. We use ReaxFF metadynamics molecular simulations to demonstrate striking differences in the free energy of CO 2 conversion to H 2 CO 3 in bulk and nanoconfined aqueous environments. We find that nanoconfinement not only reduces the energy barrier but also reverses the reaction from endothermic in bulk water to exothermic in nanoconfined water. Also, charged intermediates are observed more often under nanoconfinement than in bulk water. Stronger solvation and more favorable proton transfer with increasing nanoconfinement enhance the thermodynamics and kinetics of the reaction. Our results provide a detailed mechanistic understanding of an important step in the carbonation process, which depends intricately on confinement, surface chemistry, and CO 2 concentration.

Topics & Concepts

MetadynamicsExothermic reactionEndothermic processReaxFFChemistryChemical physicsSolvationAqueous solutionNanoporeThermodynamicsMolecular dynamicsNanotechnologyMaterials scienceComputational chemistryPhysical chemistryAdsorptionSolventOrganic chemistryPhysicsInteratomic potentialPhase Equilibria and ThermodynamicsCO2 Sequestration and Geologic InteractionsSpectroscopy and Quantum Chemical Studies