Attosecond electron dynamics in molecular ions can be enhanced or suppressed by an initial charge, with the effect tied to the strength of electron correlation.
Tailoring Attosecond Charge Migration in Native Molecular Ions
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
Attosecond chemistry involves developing strategies to manipulate electronic coherent waves in molecules, which can influence the outcome of photoinduced reactions. While recent progress in this field calls for investigations of increasingly complex isolated or embedded systems, theoretical predictions on attosecond charge migration have remained limited to native neutral species. Since molecules in nature often carry a native charge, there is potential biological and chemical interest in determining whether attosecond charge migration is affected by an additional charge. In this study, we employ high-level correlated methods to study purely electronic dynamics induced by hole-mixing in molecular ions. Our results, obtained for a series of neutral, protonated and deprotonated molecules, reveal that the likelihood of observing attosecond electron dynamics can either be degraded or improved by the presence of an initial charge, and that the existence of the dynamics is correlated with the strength of electron correlation. These findings will stimulate further experimental and theoretical investigations into this unexplored field of attosecond dynamics in molecular ions.
fields
physics.chem-ph 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
TDDFT with the local density approximation reproduces charge migration from HOMO ionization if involved states are well described, but introduces artificial ultrafast dynamics for ionization of lower orbitals.
citing papers explorer
-
Tailoring Attosecond Charge Migration in Native Molecular Ions
Attosecond electron dynamics in molecular ions can be enhanced or suppressed by an initial charge, with the effect tied to the strength of electron correlation.
-
Real-time simulation of charge migration within the time-dependent Kohn-Sham DFT
TDDFT with the local density approximation reproduces charge migration from HOMO ionization if involved states are well described, but introduces artificial ultrafast dynamics for ionization of lower orbitals.