Issue 33, 2023, Issue in Progress

Formic and acetic acid pKa values increase under nanoconfinement

Abstract

Organic acids are prevalent in the environment and their acidity and the corresponding dissociation constants can change under varying environmental conditions. The impact of nanoconfinement (when acids are confined within nanometer-scale domains) on physicochemical properties of chemical species is poorly understood and is an emerging field of study. By combining infrared and Raman spectroscopies with molecular dynamics (MD) simulations, we quantified the effect of nanoconfinement in silica nanopores on one of the fundamental chemical reactions—the dissociation of organic acids. The pKa of formic and acetic acids confined within cylindrical silica nanopores with 4 nm diameters were measured. MD models were constructed to calculate the shifts in the pKa values of acetic acid nanoconfined within 1, 2, 3, and 4 nm silica slit pores. Both experiments and MD models indicate a decrease in the apparent acid dissociation constants (i.e., increase in the pKa values) when organic acids are nanoconfined. Therefore, nanoconfinement stabilizes the protonated species. We attribute this observation to (1) a decrease in the average dielectric response of nanoconfined aqueous solutions where charge screening may be decreased; or (2) an increase in proton concentration inside nanopores, which would shift the equilibrium towards the protonated form. Overall, the results of this study provide the first quantification of the pKa values for nanoconfined formic and acetic acids and pave the way for a unifying theory predicting the impact of nanoconfinement on acid–base chemistry.

Graphical abstract: Formic and acetic acid pKa values increase under nanoconfinement

Supplementary files

Article information

Article type
Paper
Submitted
12 Dec 2022
Accepted
22 Jun 2023
First published
01 Aug 2023
This article is Open Access
Creative Commons BY-NC license

RSC Adv., 2023,13, 23147-23157

Formic and acetic acid pKa values increase under nanoconfinement

I. Sit, B. T. Fashina, A. P. Baldo, K. Leung, V. H. Grassian and A. G. Ilgen, RSC Adv., 2023, 13, 23147 DOI: 10.1039/D2RA07944E

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