Your search keyword '"Minns, R. S."' showing total 2 results

1. Structural dynamics around a hydrogen bond: Investigating the effect of hydrogen bond strengths on the excited state dynamics of carboxylic acid dimers.

Author

Plackett, E., Robertson, C., De Matos Loja, A., McGhee, H., Karras, G., Sazanovich, I. V., Ingle, R. A., Paterson, M. J., and Minns, R. S.

Subjects

BOND strengths, HYDROGEN bonding, EXCITED states, STRUCTURAL dynamics, DIMERS, PROTON transfer reactions, INFRARED absorption, CARBOXYLIC acids, ACETIC acid

Abstract

The photochemical dynamics of the acetic acid and trifluoro-acetic acid dimers in hexane are studied using time-resolved infrared absorption spectroscopy and ab initio electronic structure calculations. The different hydrogen bond strengths of the two systems lead to changes in the character of the accessed excited states and in the timescales of the initial structural rearrangement that define the early time dynamics following UV excitation. The much stronger hydrogen bonding in the acetic acid dimer stabilizes the system against dissociation. Ground state recovery is mediated by a structural buckling around the hydrogen bond itself with no evidence for excited state proton transfer processes that are usually considered to drive ultrafast relaxation processes in hydrogen bonded systems. The buckling of the ring leads to relaxation through two conical intersections and the eventual reformation of the electronic and vibrational ground states on a few picosecond timescale. In trifluoro-acetic acid, the weaker hydrogen bonding interaction means that the dimer dissociates under similar irradiation conditions. The surrounding solvent cage restricts the full separation of the monomer components, meaning that the dimer is reformed and returns to the ground state structure via a similar buckled structure but over a much longer, ∼100 ps, timescale. [ABSTRACT FROM AUTHOR]

Published

2024

2. Hydrogen Bonds in Excited State Proton Transfer.

Author

Horke, D. A., Watts, H. M., Smith, A. D., Jager, E., Springate, E., Alexander, O., Cacho, C., Chapman, R. T., and Minns, R. S.

Subjects

*HYDROGEN bonding, *PROTON transfer reactions, *CHROMOPHORES

Abstract

Hydrogen bonding interactions between biological chromophores and their surrounding protein and solvent environment significantly affect the photochemical pathways of the chromophore and its biological function. A common first step in the dynamics of these systems is excited state proton transfer between the noncovalently bound molecules, which stabilizes the system against dissociation and principally alters relaxation pathways. Despite such fundamental importance, studying excited state proton transfer across a hydrogen bond has proven difficult, leaving uncertainties about the mechanism. Through time-resolved photoelectron imaging measurements, we demonstrate how the addition of a single hydrogen bond and the opening of an excited state proton transfer channel dramatically changes the outcome of a photochemical reaction, from rapid dissociation in the isolated chromophore to efficient stabilization and ground state recovery in the hydrogen bonded case, and uncover the mechanism of excited state proton transfer at a hydrogen bond, which follows sequential hydrogen and charge transfer processes. [ABSTRACT FROM AUTHOR]

Published

2016