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Multiple heteroatom substitution effect on destructive quantum interference in tripodal single-molecule junctions

Fayu Qu, Zhihao Zhao, Xiao‐Rui Ren, Shoufeng Zhang, Lin Wang, Dong Wang

2022Physical Chemistry Chemical Physics10 citationsDOI

Abstract

). This is generally consistent with the movement or even removal of the antiresonance dips in transmission spectra. The substituent on position 2 can raise the antiresonance energy, while the substituent on position 4 or 6 can lower the antiresonance energy. When more than one nitrogen atom is incorporated, the impact of the substitution on positions 4 and 6 can be superimposed and the substitution on positions 2 and 4 can be partly cancelled. The experimental single-molecule conductance for tripodal molecules follows the trend of 0N-3SMe < 1N-3SMe < 3N-3SMe < 2N-3SMe, in agreement with the theoretical prediction. Additionally, the regulation is the intrinsic property depending on the position and number of the nitrogen atoms in the backbone and is irrelevant to the number and type of the anchoring groups. Our findings provide qualitative guidance for tuning the electron transport based on DQI in heterocycle molecular devices.

Topics & Concepts

HeteroatomSubstitution (logic)MoleculeInterference (communication)Quantum interferenceChemistryQuantumPhysicsOrganic chemistryTelecommunicationsComputer scienceQuantum mechanicsChannel (broadcasting)Ring (chemistry)Programming languageMolecular Junctions and NanostructuresQuantum and electron transport phenomenaNanowire Synthesis and Applications
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