Electronic Conductance Behavior of Carbon-Based Molecular Junctions with Conjugated Structures

Anariba, Franklin; McCreery, Richard L.

doi:10.1021/jp026285e

Cited by 100 publications

(103 citation statements)

References 45 publications

(106 reference statements)

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“…16,21,37,38 RESULTS AND DISCUSSION these values agree with previous experimental reports using single-molecule and large-area junctions. 27,[38][39][40][41][42][43][44][45] These results presented here also agree with theoretical calculations by Ratner and coworkers; these authors predict (using density functional theory, DFT) a value of  = ~0.3 Å -1 for SAMs of polyphenyldithiolates by assuming a continuous conjugation of the molecules with the metal electrodes. 17 We compared the electrical properties of SAMs of SPh n to SAMs of C≡CPh n on Au TS (Figure 2b).…”

Section: Introductionsupporting

confidence: 91%

Tunneling across SAMs Containing Oligophenyl Groups

et al. 2016

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This paper describes rates of charge tunneling across self-assembled monolayers (SAMs) of compounds containing oligophenyl groups, supported on gold and silver, using Ga 2 O 3 /EGaIn as the top electrode. It compares the injection current, J 0 , and the attenuation constant, β, of the simplified Simmons equation, across oligophenyl groups (R = Ph n ; n = 1, 2, 3), with three different anchoring groups (thiol, HSR; methanethiol, HSCH 2 R; and acetylene, HC≡CR) that attach R to the template-stripped gold and silver substrates. The results demonstrate that the structure of the molecules between the anchoring group (-S-or -C≡C-) and the oligophenyl moiety significantly influences charge transport. SAMs of SPh n , and C≡CPh n on gold show similar values of β and log|J 0 | (β = 0.28 ± 0.03 Å -1 and log|J 0 | = 2.7 ± 0.1 for Au/SPh n ; β = 0.30 ± 0.02 Å -1 and log|J 0 | = 3.0 ± 0.1 for Au/C≡CPh n ). The introduction of a single intervening methylene (CH 2 ) group, between the anchoring sulfur atom and the aromatic units to generate SAMs of SCH 2 Ph n , increases β to ~0.6 Å -1 on both gold and silver substrates. (For nalkanethiolates on gold the corresponding values are β = 0.76 Å -1 and log|J 0 | = 4.2). As a generalization, based on this and other work, it seems that increasing the height of the tunneling barrier in the region of the interfaces increases β, and may decrease J 0 ; by contrast, it appears that lowering the height of the barrier at these interfaces has little influence on β or J 0 .

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Section: Introductionsupporting

confidence: 91%

Tunneling across SAMs Containing Oligophenyl Groups

et al. 2016

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“…1͑d͒. Indeed, Anariba and Mcreery have shown that the current magnitude through a twisted terphenyl structure is lower than through the planar structure, 21 again validating our idea that qualitative trends in molecular conductances can be predicted using this simple model and the ideas of delocalization and symmetry breaking.…”

Section: Breaking Symmetry: Rotating the Central Phenyl Ringsupporting

confidence: 74%

Symmetry, delocalization, and molecular conductance

Delaney

Nolan

Greer

2005

The Journal of Chemical Physics

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Molecules bonded between two metal contacts form the simplest possible molecular devices. Coupled by the molecule, the left and right contact-based states form symmetric and antisymmetric pairs near the Fermi level. We relate the size of the resulting energy splitting ⌬E to the symmetry and degree of delocalization of the coupling molecular orbital. Qualitative trends in molecular conductances are then estimated from the variations in ⌬E. We examine benzenedithiol and other molecules of interest in transport.

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“…2C). [69,[136][137][138] Related paradigms involve using eutectic Ga/In (eGaIn, melting point $16 8C) on SAMs at Ag, [139] Hg on adlayers bonded to flat carbon, [71,72,140] and Hg on a molecular layer at silicon. [141] A liquid metal top contact circumvents the use of vapor phase atoms, so metal incursion into the molecular layer is less likely.…”

Section: Progress With Ensemble Molecular Junctionsmentioning

confidence: 99%

Progress with Molecular Electronic Junctions: Meeting Experimental Challenges in Design and Fabrication

2009

Self Cite

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Molecular electronics seeks to incorporate molecular components as functional elements in electronic devices. There are numerous strategies reported to date for the fabrication, design, and characterization of such devices, but a broadly accepted example showing structure-dependent conductance behavior has not yet emerged. This progress report focuses on experimental methods for making both single-molecule and ensemble molecular junctions, and highlights key results from these efforts. Based on some general objectives of the field, particular experiments are presented to show progress in several important areas, and also to define those areas that still need attention. Some of the variable behavior of ostensibly similar junctions reported in the literature is attributable to differences in the way the junctions are fabricated. These differences are due, in part, to the multitude of methods for supporting the molecular layer on the substrate, including methods that utilize physical adsorption and covalent bonds, and to the numerous strategies for making top contacts. After discussing recent experimental progress in molecular electronics, an assessment of the current state of the field is presented, along with a proposed road map that can be used to assess progress in the future.

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Electronic Conductance Behavior of Carbon-Based Molecular Junctions with Conjugated Structures

Cited by 100 publications

References 45 publications

Tunneling across SAMs Containing Oligophenyl Groups

Tunneling across SAMs Containing Oligophenyl Groups

Symmetry, delocalization, and molecular conductance

Progress with Molecular Electronic Junctions: Meeting Experimental Challenges in Design and Fabrication

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