Document Type
Article
Publication Date
3-2-2023
Abstract
Charge migration (CM) is a coherent attosecond process that involves the movement of localized holes across a molecule. To determine the relationship between a molecule's structure and the CM dynamics it exhibits, we perform systematic studies of para-functionalized bromobenzene molecules (X-C6H4-R) using real-time time-dependent density functional theory. We initiate valence-electron dynamics by emulating rapid strong-field ionization leading to a localized hole on the bromine atom. The resulting CM, which takes on the order of 1 fs, occurs via an X localized → C6H4delocalized → R localized mechanism. Interestingly, the hole contrast on the acceptor functional group increases with increasing electron-donating strength. This trend is well-described by the Hammett σ value of the group, which is a commonly used metric for quantifying the effect of functionalization on the chemical reactivity of benzene derivatives. These results suggest that simple attochemistry principles and a density-based picture can be used to predict and understand CM.
Publication Source (Journal or Book title)
Journal of Physical Chemistry A
First Page
1894
Last Page
1900
Recommended Citation
Folorunso, A., Mauger, F., Hamer, K., Jayasinghe, D., Wahyutama, I., Ragains, J., Jones, R., Dimauro, L., Gaarde, M., Schafer, K., & Lopata, K. (2023). Attochemistry Regulation of Charge Migration. Journal of Physical Chemistry A, 127 (8), 1894-1900. https://doi.org/10.1021/acs.jpca.3c00568