期刊
APPLIED SCIENCES-BASEL
卷 11, 期 8, 页码 -出版社
MDPI
DOI: 10.3390/app11083317
关键词
molecular electronics; single-molecule junctions; STM break-junction; in-situ isomerisation; carotenoids
类别
资金
- ERC [Fields4CAT-772391]
- European Union
- Plus 3 program of the Boehringer Ingelheim Foundation
- National Research Foundation of Korea [NRF-2020R1A2C1010724]
- Powered@NLHPC
- NLHPC [ECM-02]
External electric fields have been shown to catalyse chemical reactions efficiently, even those inaccessible via wet-chemical synthesis. Single-molecule junctions of carotenoids have been electrically characterized to show distinct conductance signatures for the trans and cis isomers. The electric field is found to polarize the molecule, mix excited states, and promote both isomerization and electron transport within the molecule.
External electric fields (EEFs) have proven to be very efficient in catalysing chemical reactions, even those inaccessible via wet-chemical synthesis. At the single-molecule level, oriented EEFs have been successfully used to promote in situ single-molecule reactions in the absence of chemical catalysts. Here, we elucidate the effect of an EEFs on the structure and conductance of a molecular junction. Employing scanning tunnelling microscopy break junction (STM-BJ) experiments, we form and electrically characterize single-molecule junctions of two tetramethyl carotene isomers. Two discrete conductance signatures show up more prominently at low and high applied voltages which are univocally ascribed to the trans and cis isomers of the carotenoid, respectively. The difference in conductance between both cis-/trans- isomers is in concordance with previous predictions considering pi-quantum interference due to the presence of a single gauche defect in the trans isomer. Electronic structure calculations suggest that the electric field polarizes the molecule and mixes the excited states. The mixed states have a (spectroscopically) allowed transition and, therefore, can both promote the cis-isomerization of the molecule and participate in electron transport. Our work opens new routes for the in situ control of isomerisation reactions in single-molecule contacts.
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