Lower degree of dissociation of pyruvic acid at water surfaces than in bulk

Dominika Lesnicki; Veronika Wank; Jenée D. Cyran; Ellen H.G. Backus; Marialore Sulpizi

doi:10.1039/d2cp01293f

Lower degree of dissociation of pyruvic acid at water surfaces than in bulk

Dominika Lesnicki, Veronika Wank, Jenée D. Cyran, Ellen H.G. Backus, Marialore Sulpizi

Chemistry Department

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Abstract

Understanding the acid/base behavior of environmentally relevant organic acids is of key relevance for accurate climate modelling. Here we investigate the effect of pH on the (de)protonation state of pyruvic acid at the air-water interface and in bulk by using the analytical techniques surface-specific vibrational sum frequency generation and attenuated total reflection spectroscopy. To provide a molecular interpretation of the observed behavior, simulations are carried out using a free energy perturbation approach in combination with electronic structure-based molecular dynamics. In both the experimental and theoretical results we observe that the protonated form of pyruvic acid is preferred at the air-water interface. The increased proton affinity is the result of the specific microsolvation at the interface.

Original language	English
Pages (from-to)	13510-13513
Number of pages	4
Journal	Physical Chemistry Chemical Physics
Volume	24
Issue number	22
DOIs	https://doi.org/10.1039/d2cp01293f
State	Published - 10 May 2022

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abstract = "Understanding the acid/base behavior of environmentally relevant organic acids is of key relevance for accurate climate modelling. Here we investigate the effect of pH on the (de)protonation state of pyruvic acid at the air-water interface and in bulk by using the analytical techniques surface-specific vibrational sum frequency generation and attenuated total reflection spectroscopy. To provide a molecular interpretation of the observed behavior, simulations are carried out using a free energy perturbation approach in combination with electronic structure-based molecular dynamics. In both the experimental and theoretical results we observe that the protonated form of pyruvic acid is preferred at the air-water interface. The increased proton affinity is the result of the specific microsolvation at the interface.",

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AU - Lesnicki, Dominika

AU - Wank, Veronika

AU - Cyran, Jenée D.

AU - Backus, Ellen H.G.

AU - Sulpizi, Marialore

PY - 2022/5/10

Y1 - 2022/5/10

N2 - Understanding the acid/base behavior of environmentally relevant organic acids is of key relevance for accurate climate modelling. Here we investigate the effect of pH on the (de)protonation state of pyruvic acid at the air-water interface and in bulk by using the analytical techniques surface-specific vibrational sum frequency generation and attenuated total reflection spectroscopy. To provide a molecular interpretation of the observed behavior, simulations are carried out using a free energy perturbation approach in combination with electronic structure-based molecular dynamics. In both the experimental and theoretical results we observe that the protonated form of pyruvic acid is preferred at the air-water interface. The increased proton affinity is the result of the specific microsolvation at the interface.

AB - Understanding the acid/base behavior of environmentally relevant organic acids is of key relevance for accurate climate modelling. Here we investigate the effect of pH on the (de)protonation state of pyruvic acid at the air-water interface and in bulk by using the analytical techniques surface-specific vibrational sum frequency generation and attenuated total reflection spectroscopy. To provide a molecular interpretation of the observed behavior, simulations are carried out using a free energy perturbation approach in combination with electronic structure-based molecular dynamics. In both the experimental and theoretical results we observe that the protonated form of pyruvic acid is preferred at the air-water interface. The increased proton affinity is the result of the specific microsolvation at the interface.

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Lower degree of dissociation of pyruvic acid at water surfaces than in bulk

Abstract

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