Mechanical Stretching-Induced Electron-Transfer Reactions and Conductance Switching in Single Molecules

Yueqi Li; Naomi L. Haworth; Limin Xiang; Simone Ciampi; Michelle L. Coote; Nongjian Tao

doi:10.1021/jacs.7b08239

Mechanical Stretching-Induced Electron-Transfer Reactions and Conductance Switching in Single Molecules

Yueqi Li, Naomi L. Haworth, Limin Xiang, Simone Ciampi^*, Michelle L. Coote, Nongjian Tao

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

62 Citations (Scopus)

Abstract

A central idea in electron-transfer theories is the coupling of the electronic state of a molecule to its structure. Here we show experimentally that fine changes to molecular structures by mechanically stretching a single metal complex molecule via changing the metal-ligand bond length can shift its electronic energy levels and predictably guide electron-transfer reactions, leading to the changes in redox state. We monitor the redox state of the molecule by tracking its characteristic conductance, determine the shift in the redox potential due to mechanical stretching of the metal-ligand bond, and perform model calculations to provide insights into the observations. The work reveals that a mechanical force can shift the redox potential of a molecule, change its redox state, and thus allow the manipulation of single molecule conductance.

Original language	English
Pages (from-to)	14699-14706
Number of pages	8
Journal	Journal of the American Chemical Society
Volume	139
Issue number	41
DOIs	https://doi.org/10.1021/jacs.7b08239
Publication status	Published - 18 Oct 2017

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title = "Mechanical Stretching-Induced Electron-Transfer Reactions and Conductance Switching in Single Molecules",

abstract = "A central idea in electron-transfer theories is the coupling of the electronic state of a molecule to its structure. Here we show experimentally that fine changes to molecular structures by mechanically stretching a single metal complex molecule via changing the metal-ligand bond length can shift its electronic energy levels and predictably guide electron-transfer reactions, leading to the changes in redox state. We monitor the redox state of the molecule by tracking its characteristic conductance, determine the shift in the redox potential due to mechanical stretching of the metal-ligand bond, and perform model calculations to provide insights into the observations. The work reveals that a mechanical force can shift the redox potential of a molecule, change its redox state, and thus allow the manipulation of single molecule conductance.",

author = "Yueqi Li and Haworth, {Naomi L.} and Limin Xiang and Simone Ciampi and Coote, {Michelle L.} and Nongjian Tao",

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AU - Li, Yueqi

AU - Haworth, Naomi L.

AU - Xiang, Limin

AU - Ciampi, Simone

AU - Coote, Michelle L.

AU - Tao, Nongjian

PY - 2017/10/18

Y1 - 2017/10/18

N2 - A central idea in electron-transfer theories is the coupling of the electronic state of a molecule to its structure. Here we show experimentally that fine changes to molecular structures by mechanically stretching a single metal complex molecule via changing the metal-ligand bond length can shift its electronic energy levels and predictably guide electron-transfer reactions, leading to the changes in redox state. We monitor the redox state of the molecule by tracking its characteristic conductance, determine the shift in the redox potential due to mechanical stretching of the metal-ligand bond, and perform model calculations to provide insights into the observations. The work reveals that a mechanical force can shift the redox potential of a molecule, change its redox state, and thus allow the manipulation of single molecule conductance.

AB - A central idea in electron-transfer theories is the coupling of the electronic state of a molecule to its structure. Here we show experimentally that fine changes to molecular structures by mechanically stretching a single metal complex molecule via changing the metal-ligand bond length can shift its electronic energy levels and predictably guide electron-transfer reactions, leading to the changes in redox state. We monitor the redox state of the molecule by tracking its characteristic conductance, determine the shift in the redox potential due to mechanical stretching of the metal-ligand bond, and perform model calculations to provide insights into the observations. The work reveals that a mechanical force can shift the redox potential of a molecule, change its redox state, and thus allow the manipulation of single molecule conductance.

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EP - 14706

JO - Journal of the American Chemical Society

JF - Journal of the American Chemical Society

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ER -

Mechanical Stretching-Induced Electron-Transfer Reactions and Conductance Switching in Single Molecules

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