Open AccessMolecular Modes of Attosecond Charge Migration
Author(s) -
Aderonke S. Folorunso,
Adam Bruner,
François Mauger,
Kyle Hamer,
Samuel Hernández,
R. R. Jones,
Louis F. DiMauro,
Mette B. Gaarde,
Kenneth J. Schäfer,
Kenneth A. Lopata
Publication year - 2021
Publication title -
physical review letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.688
H-Index - 673
eISSN - 1079-7114
pISSN - 0031-9007
DOI - 10.1103/physrevlett.126.133002
Subject(s) - attosecond , molecule , halogen , ionization , charge (physics) , physics , atomic physics , molecular physics , density functional theory , chemical physics , materials science , chemistry , quantum mechanics , ion , laser , alkyl , organic chemistry , ultrashort pulse
First-principles calculations are employed to elucidate the modes of attosecond charge migration (CM) in halogenated hydrocarbon chains. We use constrained density functional theory (DFT) to emulate the creation of a localized hole on the halogen and follow the subsequent dynamics via time-dependent DFT. We find low-frequency CM modes (∼1 eV) that propagate across the molecule and study their dependence on length, bond order, and halogenation. We observe that the CM speed (∼4 Å/fs) is largely independent of molecule length, but is lower for triple-bonded versus double-bonded molecules. Additionally, as the halogen mass increases, the hole travels in a more particlelike manner as it moves across the molecule. These heuristics will be useful in identifying molecules and optimal CM detection methods for future experiments, especially for halogenated hydrocarbons which are promising targets for ionization-triggered CM.
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