Reactions at solid-water interfaces play a foundational role in water treatment systems, catalysis, and chemical separations, and in predicting chemical fate and transport in the environment. Over the last century, experimental measurements and computational models have made tremendous progress in capturing reactions at solid surfaces. The interfacial reactivity of a solid surface, however, can change dramatically and unexpectedly when it is confined to the nanoscale. Nanoconfinement can arise in different geometries such as pores/cages (3D confinement), channels (2D confinement), and slits (1D confinement). Therefore, measurements on unconfined surfaces, and molecular models parameterized based on these measurements, fail to capture chemical behaviors under nanoconfinement. This review evaluates recent experimental and theoretical advances, with a focus on adsorption at solid-water interfaces. We review how nanoconfinement alters the physico-chemical properties of water, and how the structure and dynamics of nanoconfined water dictate energetics, pathways, and products of adsorption in nanopores. Finally, the implications of these findings and future research directions are discussed.
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Article Synopsis
- Solid-water interfaces play a key role in various physical and chemical processes, and their study often involves surface-specific sum-frequency generation (SFG) spectroscopy coupled with molecular dynamics (MD) simulations for accurate results.! -
- Traditional MD simulations require long time frames (a few nanoseconds) to produce reliable data, which can be a limitation when using computationally intensive methods like ab initio MD (AIMD) for complex interfaces.! -
- This research introduces machine learning (ML) techniques to speed up AIMD simulations and SFG spectrum calculations, making it easier and cheaper to analyze complicated solid-water systems effectively.!
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