AI Article Synopsis
- A model was created to explain how electron transfer in a molecular junction works, focusing on the roles of π and π* orbitals of a fluorophore in generating current and electroluminescence (EL).
- The study showed that current and EL change in steps near a critical voltage, influenced by both electron transfer processes and transitions within the molecule.
- By analyzing the behavior of current and EL and comparing it with experimental data from a ZnPc-based junction, researchers gained insights into the physical mechanisms at play and determined energy values for the molecule's frontier orbitals and states involved in the optoelectronic processes.
Article Abstract
A model of the optoelectronic process in a molecular junction has been developed, in which electron transfer occurs through transmission channels associated with the filling of the π and π* orbitals of the fluorophore with transferred electrons. The contribution of each channel to the formation of current and electroluminescence (EL) is determined by the probability of the realization of those electronic states of the molecule that, at a given bias voltage, are involved in electron transfer. It is shown that in the vicinity of critical bias voltage, stepwise changes in current and EL occur, and the height of each step is controlled by kinetic processes associated with both electron transfer and intramolecular transitions. Using the obtained analytical expressions for the relative intensities of the emission lines X and X and comparing theoretical results with experimental data on STM-induced EL in a ZnPc-based junction, we showed that the method for analyzing the behavior of current and EL near critical voltages can serve as an effective tool for understanding the physical mechanisms responsible for optoelectronic processes at the single-molecule level. The method also made it possible to obtain real values of the energy of the Frontier orbitals of the ZnPc molecule embedded between the electrodes, as well as the energies of those electronic states of the neutral and charged molecules that participate in the optoelectronic process, including electrofluorochromism.
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| http://dx.doi.org/10.1039/d4cp01328j | DOI Listing |
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