Abstract
Charge migration is the electronic response that immediately follows localized ionization or excitation in a molecule, before the nuclei have time to move. It typically unfolds on sub-femtosecond time scales and most often corresponds to dynamics far from equilibrium, involving multi-electron interactions in a complex chemical environment. While charge migration has been documented experimentally and theoretically in multiple organic and inorganic compounds, the general mechanism that regulates it remains unsettled. In this work we use tools from nonlinear dynamics to analyze charge migration that takes place along the backbone of conjugated hydrocarbons, which we simulate using time-dependent density functional theory. In this electron-density framework we show that charge migration modes emerge as attosecond solitons and demonstrate the same type of solitary-wave dynamics in both simplified model systems and full three-dimensional molecular simulations. We show that these attosecond-soliton modes result from a balance between dispersion and nonlinear effects tied to time-dependent multi-electron interactions.%Our soliton-mode mechanism, and the nonlinear tools we use to analyze it, pave the way for understanding migration dynamics in a broad range of organic molecules.%For instance, we demonstrate the opportunities for chemically steering charge migration via molecular functionalization, which can alter both the initially localized electron perturbation and its subsequent time evolution.
Highlights
The movement of electrons and holes in matter regulates many physical and chemical processes such as chemical reactions, photosynthesis and photovoltaics, and charge transfer [1,2]
In the density picture we showed that periodic charge migration (CM) modes, with a hole traveling back and forth through the π system in a particlelike manner, emerge as solitary waves
For a detailed quantitative prediction of CM modes like their precise period or other metrics associated with the CM dynamics [22], one needs a detailed modeling of the molecular system
Summary
The movement of electrons and holes in matter regulates many physical and chemical processes such as chemical reactions, photosynthesis and photovoltaics, and charge transfer [1,2]. We leverage tools from nonlinear dynamics to study (sub-)femtosecond field-free CM unfolding in conjugated organic molecules following the sudden creation of a localized hole in the system, a paradigm for site-specific ionization. This is motivated by the fact that nonlinear dynamics [23,24] has developed general-purpose methods for tackling and understanding the structure of high-dimensional phase spaces. We discuss the implication of our results for future theoretical and experimental CM studies, including the opportunities for chemically steering CM by molecular functionalization, both in creating the initially localized electron hole and for its subsequent time evolution.
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