Quantitative analysis of weak current rectification in molecular tunnel junctions subject to mechanical deformation reveals two different rectification mechanisms for oligophenylene thiols alkane thiols
Metal-molecule-metal junctions based on alkane thiol (C n T) and oligophenylene thiol (OPT n ) self-assembled monolayers (SAMs) and Au electrodes are expected to exhibit similar electrical asymmetry, as both junctions have one chemisorbed Au-S contact and one physisorbed, van der Waals contact. Asym...
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| Published in | Nanoscale Vol. 13; no. 39; pp. 16755 - 16768 |
|---|---|
| Main Authors | , , , |
| Format | Journal Article |
| Published |
14.10.2021
|
| Online Access | Get full text |
| ISSN | 2040-3364 2040-3372 |
| DOI | 10.1039/d1nr04410a |
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| Abstract | Metal-molecule-metal junctions based on alkane thiol (C
n
T) and oligophenylene thiol (OPT
n
) self-assembled monolayers (SAMs) and Au electrodes are expected to exhibit similar electrical asymmetry, as both junctions have one chemisorbed Au-S contact and one physisorbed, van der Waals contact. Asymmetry is quantified by the current rectification ratio RR apparent in the current-voltage (
I
-
V
) characteristics. Here we show that RR
<
1 for C
n
T and RR
>
1 for OPT
n
junctions, in contrast to expectation, and further, that RR behaves very differently for C
n
T and OPT
n
junctions under mechanical extension using the conducting probe atomic force microscopy (CP-AFM) testbed. The analysis presented in this paper, which leverages results from the previously validated single level model and
ab initio
quantum chemical calculations, allows us to explain the puzzling experimental findings for C
n
T and OPT
n
in terms of different current rectification mechanisms. Specifically, in C
n
T-based junctions the Stark effect creates the HOMO level shifting necessary for rectification, while for OPT
n
junctions the level shift arises from position-dependent coupling of the HOMO wavefunction with the junction electrostatic potential profile. On the basis of these mechanisms, our quantum chemical calculations allow quantitative description of the impact of mechanical deformation on the measured current rectification. Additionally, our analysis, matched to experiment, facilitates direct estimation of the impact of intramolecular electrostatic screening on the junction potential profile. Overall, our examination of current rectification in benchmark molecular tunnel junctions illuminates key physical mechanisms at play in single step tunneling through molecules, and demonstrates the quantitative agreement that can be obtained between experiment and theory in these systems.
Despite similar chemical asymmetry, molecular junctions based on alkane thiols (C
n
T) and oligophenylene thiols (OPT
n
) exhibit opposite current rectification and different behavior under mechanical deformation. |
|---|---|
| AbstractList | Metal-molecule-metal junctions based on alkane thiol (C
n
T) and oligophenylene thiol (OPT
n
) self-assembled monolayers (SAMs) and Au electrodes are expected to exhibit similar electrical asymmetry, as both junctions have one chemisorbed Au-S contact and one physisorbed, van der Waals contact. Asymmetry is quantified by the current rectification ratio RR apparent in the current-voltage (
I
-
V
) characteristics. Here we show that RR
<
1 for C
n
T and RR
>
1 for OPT
n
junctions, in contrast to expectation, and further, that RR behaves very differently for C
n
T and OPT
n
junctions under mechanical extension using the conducting probe atomic force microscopy (CP-AFM) testbed. The analysis presented in this paper, which leverages results from the previously validated single level model and
ab initio
quantum chemical calculations, allows us to explain the puzzling experimental findings for C
n
T and OPT
n
in terms of different current rectification mechanisms. Specifically, in C
n
T-based junctions the Stark effect creates the HOMO level shifting necessary for rectification, while for OPT
n
junctions the level shift arises from position-dependent coupling of the HOMO wavefunction with the junction electrostatic potential profile. On the basis of these mechanisms, our quantum chemical calculations allow quantitative description of the impact of mechanical deformation on the measured current rectification. Additionally, our analysis, matched to experiment, facilitates direct estimation of the impact of intramolecular electrostatic screening on the junction potential profile. Overall, our examination of current rectification in benchmark molecular tunnel junctions illuminates key physical mechanisms at play in single step tunneling through molecules, and demonstrates the quantitative agreement that can be obtained between experiment and theory in these systems.
Despite similar chemical asymmetry, molecular junctions based on alkane thiols (C
n
T) and oligophenylene thiols (OPT
n
) exhibit opposite current rectification and different behavior under mechanical deformation. |
| Author | Frisbie, C. Daniel Bâldea, Ioan Nguyen, Quyen Van Xie, Zuoti |
| AuthorAffiliation | Guangdong Technion-Israel Institute of Technology Theoretical Chemistry University of Minnesota Heidelberg University Department of Materials Science and Engineering Department of Chemical Engineering and Materials Science |
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| Notes | 10.1039/d1nr04410a Electronic supplementary information (ESI) available: Experimental and theoretical details, supplementary tables and figures. See DOI |
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| References_xml | – issn: 1981 publication-title: Physics of Semiconductor Devices doi: Sze – issn: 1977 issue: 36 end-page: 205-344 publication-title: Advances in Chemical Physics doi: Cederbaum Domcke – issn: 1999 publication-title: Electronic Transport in Mesoscopic Systems doi: Datta – issn: 2016 publication-title: Gaussian 16, Revision B.01 doi: Frisch Trucks Schlegel Scuseria Robb Cheeseman Scalmani Barone Petersson Nakatsuji Li Caricato Marenich Bloino Janesko Gomperts Mennucci Hratchian Ortiz Izmaylov Sonnenberg Williams-Young Ding Lipparini Egidi Goings Peng Petrone Henderson Ranasinghe Zakrzewski Gao Rega Zheng Liang Hada Ehara Toyota Fukuda Hasegawa Ishida Nakajima Honda Kitao Nakai Vreven Throssell Montgomery Jr. Ogliaro Bearpark Heyd Brothers Kudin Staroverov Keith Kobayashi Normand Raghavachari Rendell Burant Iyengar Tomasi Cossi Millam Klene Adamo Cammi Ochterski Martin Morokuma Farkas Foresman Fox – issn: 2003 issue: 3 volume-title: Electrical conduction through molecules publication-title: Advanced semiconductors and organic nano-techniques doi: Zahid Paulsson Datta |
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| Snippet | Metal-molecule-metal junctions based on alkane thiol (C
n
T) and oligophenylene thiol (OPT
n
) self-assembled monolayers (SAMs) and Au electrodes are expected... |
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| Title | Quantitative analysis of weak current rectification in molecular tunnel junctions subject to mechanical deformation reveals two different rectification mechanisms for oligophenylene thiols alkane thiols |
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