Highly Conducting π-Conjugated Molecular Junctions Covalently Bonded to Gold Electrodes

Chen, Wenbo; Widawsky, Jonathan R.; Vázquez, Héctor; Schneebeli, Severin T.; Hybertsen, Mark S.; Breslow, Ronald; Venkataraman, Latha

doi:10.1021/ja208020j

Cited by 173 publications

(260 citation statements)

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“…11 However, it turned out that the transport-limiting barriers shifted from the molecule-metal interfaces onto the molecular backbone, independently of the specific connection scheme to the fullerene. 12 In contrast to fullerenes with many, but weak sp 2 "bonds", the direct C-Au bond showed unprecedented high conductances for oligophenyls up to 0.9 G 0 , 13 (for one phenyl ring) close to the theoretical maximum of 1 G 0 (with G 0 = 2e 2 /h 77 µS the conductance quantum). The C-Au bond can be established either by extrusion of a trimethyltin moiety 13 or post deprotection of a trimethylsilyl moiety.…”

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confidence: 84%

“…12 In contrast to fullerenes with many, but weak sp 2 "bonds", the direct C-Au bond showed unprecedented high conductances for oligophenyls up to 0.9 G 0 , 13 (for one phenyl ring) close to the theoretical maximum of 1 G 0 (with G 0 = 2e 2 /h 77 µS the conductance quantum). The C-Au bond can be established either by extrusion of a trimethyltin moiety 13 or post deprotection of a trimethylsilyl moiety. 14 Currently, the direct C-electrode bond seems to be the most promising coupling scheme also for graphene electrodes 15,16 if polymerization via the free termini can be prevented.…”

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confidence: 84%

“…Due to the good agreement between DFT and experiments for both the 'monomer' and the 'dimer' compounds, we conclude that spontaneous dimerization is most likely the origin for the low-conductance peaks of compounds 4 (and also 5), in agreement with the observation of dimerization in SnMe 3 -capped oligophenyls with C-Au anchors. 13 A dimerization explains further why the contacting traces for molecular signatures are 5-7 times longer for the low-conductance I-Vs compared to the high-conductance I-V s (see SI).When comparing the main peaks in the conductance data at high bias (1.0 V) or low bias (0.2 V, see SI) of 2, 3, 4 and 5 measured at 300 K, a good qualitative agreement with DFT at zero-bias is found as directly compared in Fig. 5 B).…”

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confidence: 99%

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High-Conductive Organometallic Molecular Wires with Delocalized Electron Systems Strongly Coupled to Metal Electrodes

et al. 2014

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Besides active, functional molecular building blocks such as diodes or switches, passive components as, e.g., molecular wires, are required to realize molecular-scale electronics. Incorporating metal centers in the molecular backbone enables the molecular energy levels to be tuned in respect to the Fermi energy of the electrodes. Furthermore, by using more than one metal center and sp-bridging ligands, a strongly delocalized electron system is formed between these metallic "dopants", facilitating transport along the molecular backbone. Here, we study the influence of molecule-metal coupling on charge transport of dinuclear X(PP) 2 FeC 4 Fe(PP) 2 X molecular wires (PP = Et 2 PCH 2 CH 2 PEt 2 ); X = CN (1), NCS (2), NCSe (3), C 4 SnMe 3 (4) and C 2 SnMe 3 (5)) under ultra-high vacuum and variable temperature conditions. In contrast to 1 which showed unstable junctions at very low conductance (8.1 · 10 −7 G 0 ), 4 formed a Au-C 4 FeC 4 FeC 4 -Au junction 4 after SnMe 3 extrusion which revealed a conductance of 8.9 · 10 −3 G 0 , three orders of magnitude higher than for 2 (7.9 · 10 −6 G 0 ) and two orders of magnitude higher than for 3 (3.8 · 10 −4 G 0 ). Density functional theory (DFT) confirmed the experimental trend in the conductance for the various anchoring motifs. The strong hybridization of molecular and metal states found in the C-Au coupling case enables the delocalized electronic system of the organometallic Fe 2 backbone to be extended over the molecule-metal interfaces to the metal electrodes to establish high-conductive molecular wires.KEYWORDS: Molecular wire, Single-molecule junctions, electronic transport, break-junctions, organometallic compounds, density functional theory Molecular electronics aims at employing single molecules as functional building blocks in electronic circuits. Besides such active components which provide, e.g., current rectifying or switching properties, also passive components such as molecular wires are required for the realization of molecular-scale electronics. Generally, an ideal wire has lowest resistance with almost linear (ohmic) and length-independent (ballistic) transport properties. For molecular wires, the required high conductance can in principle be achieved if low injection barriers for charge-carriers are present at the molecule-metal interfaces, if molecular orbitals (MOs) are available close to the Fermi energy of the electrodes, and if a large degree of electronic conjugation across the backbone is present. Already the first task seems to be difficult to achieve as the most frequently used thiol anchoring 1,2 suffers from an electronically weak molecule-metal coupling. Additionally, multiple bonding sites available on the Au surface for the thiol bond give rise to alter- † IBM Research -Zurich ‡ University of Vienna ¶ University of Zurich nating energy barriers for charge-carrier injection and result in large fluctuations in the transport properties. Therefore other anchoring schemes such as nitriles, 3 isocyanides, 4 amines, 5 and pyridines 6 were ...

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High-Conductive Organometallic Molecular Wires with Delocalized Electron Systems Strongly Coupled to Metal Electrodes

et al. 2014

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“…[6][7][8][9][10][11][12][13][14][15][16][17][18] Recent studies of singlemolecule break junctions have been interpreted to indicate that the presence of covalent Au−C σ-bonds-formed using trimethyltin (-SnMe 3 )-terminated n-alkyl groups, 19,20 and SnMe 3 -terminated aromatics [19][20][21] or trimethylsilyl (TMS)-terminated conjugated systems 22 -increases rates of charge transport across these junctions by approximately a factor of 10-100, relative to amine or thiolate anchoring groups. One possible inference from the increase is that the Au−C σ-bond, and the absence of resistive anchoring heteroatoms, increases "conductivity" (although the meaning of this word is not entirely clear for tunneling junctions).…”

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confidence: 99%

Characterizing the Metal–SAM Interface in Tunneling Junctions

et al. 2015

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This paper investigates the influence of the interface between a gold or silver metal electrode and an n-alkyl SAM (supported on that electrode) on the rate of charge transport across junctions with structure Met(Au or Ag) TS /A(CH 2 ) n H//Ga 2 O 3 /EGaIn by comparing measurements of current density, J(V), for Met/AR = Au/thiolate (Au/SR), Ag/thiolate (Ag/SR), Ag/carboxylate (Ag/O 2 CR),and Au/acetylene (Au/CtCR), where R is an n-alkyl group. Values of J 0 and β (from the Simmons equation) were indistinguishable for these four interfaces. Since the anchoring groups, A, have large differences in their physical and electronic properties, the observation that they are indistinguishable in their influence on the injection current, J 0 (V = 0.5) indicates that these four Met/A interfaces do not contribute to the shape of the tunneling barrier in a way that influences J(V).

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“…[24][25][26][27] This technique enables the study of several parameters that affect the spin dependent electron transfer or the overall electron transfer, in a relatively simple manner. The same concept was applied in the past both with CP-AFM and STM for investigating length dependent [28][29][30][31][32] and force dependent conduction. 4,[33][34][35][36] The present study demonstrates the use of CP-AFM to study the spin dependent electron transfer through oligopeptide monolayers.…”

Section: Introductionmentioning

confidence: 99%

Structure dependent spin selectivity in electron transport through oligopeptides

Kiran

Cohen

Naaman

2016

The Journal of Chemical Physics

108

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The chiral-induced spin selectivity (CISS) effect entails spin-selective electron transmission through chiral molecules. In the present study, the spin filtering ability of chiral, helical oligopeptide monolayers of two different lengths is demonstrated using magnetic conductive probe atomic force microscopy. Spin-specific nanoscale electron transport studies elucidate that the spin polarization is higher for 14-mer oligopeptides than that of the 10-mer. We also show that the spin filtering ability can be tuned by changing the tip-loading force applied on the molecules. The spin selectivity decreases with increasing applied force, an effect attributed to the increased ratio of radius to pitch of the helix upon compression and increased tilt angles between the molecular axis and the surface normal. The method applied here provides new insights into the parameters controlling the CISS effect. C 2016 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license

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Highly Conducting π-Conjugated Molecular Junctions Covalently Bonded to Gold Electrodes

Cited by 173 publications

References 39 publications

High-Conductive Organometallic Molecular Wires with Delocalized Electron Systems Strongly Coupled to Metal Electrodes

High-Conductive Organometallic Molecular Wires with Delocalized Electron Systems Strongly Coupled to Metal Electrodes

Characterizing the Metal–SAM Interface in Tunneling Junctions

Structure dependent spin selectivity in electron transport through oligopeptides

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