On the multiphoton ionisation photoelectron spectra of phenol
- Diptesh Dey, Joanne L. Woodhouse, Marcus P. Taylor, Helen H. Fielding and Graham A. Worth
- Publication
- January 5, 2024
Abstract:
The phenol molecule is a prototype for non-adiabatic dynamics and the excited-state photochemistry of biomolecules. In this article, we report a joint theoretical and experimental investigation on the resonance enhanced multiphoton ionisation photoelectron (REMPI) spectra of the two lowest ionisation bands of phenol. The focus is on the theoretical interpretation of the measured spectra using quantum dynamics simulations. These were performed by numerically solving the time-dependent Schrödinger equation using the multi-layer variant of the multiconfiguration time-dependent Hartree algorithm together with a vibronic coupling Hamiltonian model. The ionising laser pulse is modelled explicitly within the ionisation continuum model to simulate experimental femtosecond 1+1 REMPI photoelectron spectra. These measured spectra are sensitive to very short lived electronically excited states, providing a rigorous benchmark for our theoretical methods. The match between experiment and theory allows for an interpretation of the features of the spectra at different wavelengths and shows that there are features due to both ‘direct’ and ‘indirect’ ionisation, resulting from non-resonant and resonant excitation by the pump pulse.
Additional Resources
DOI: 10.1039/D3CP05559K
Bibtex:
@Article{dey24otmultiphoton,
author ="Dey, Diptesh and Woodhouse, Joanne L. and Taylor, Marcus P. and Fielding, Helen H. and Worth, Graham A.",
title ="On the multiphoton ionisation photoelectron spectra of phenol",
journal ="Phys. Chem. Chem. Phys.",
year ="2024",
volume ="26",
issue ="4",
pages ="3451-3461",
publisher ="The Royal Society of Chemistry",
doi ="10.1039/D3CP05559K",
url ="http://dx.doi.org/10.1039/D3CP05559K",
}
