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Solvent-molecule interaction induced gating of charge transport through single-molecule junctions

Author(s):

Zheng Tang, Songjun Hou, Qingqing Wu, Zhibing Tan, Jueting Zheng, Ruihao Li, Junyang Liu, Yang Yang, Hatef Sadeghi, Jia Shi, Iain Grace, Colin J. Lambert, Wenjing Hong

Journal:

Science Bulletin

Year:

2020

Volume:

65

Pages

944-950

DOI:

10.1016/j.scib.2020.03.012

Abstract:

To explore solvent gating of single-molecule electrical conductance due to solvent-molecule interactions, charge transport through single-molecule junctions with different anchoring groups in various solvent environments was measured by using the mechanically controllable break junction technique. We found that the conductance of single-molecule junctions can be tuned by nearly an order of magnitude by varying the polarity of solvent. Furthermore, gating efficiency due to solvent–molecule interactions was found to be dependent on the choice of the anchor group. Theoretical calculations revealed that the polar solvent shifted the molecular-orbital energies, based on the coupling strength of the anchor groups. For weakly coupled molecular junctions, the polar solvent–molecule interaction was observed to reduce the energy gap between the molecular orbital and the Fermi level of the electrode and shifted the molecular orbitals. This resulted in a more significant gating effect than that of the strongly coupled molecules. This study suggested that solvent–molecule interaction can significantly affect the charge transport through single-molecule junctions.

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