Covalently Bonded Organic Monolayers on a Carbon Substrate:  A New Paradigm for Molecular Electronics

Ranganathan, Srikanth; Steidel, Ilson; Anariba, Franklin; McCreery, Richard L.

doi:10.1021/nl015566f

Cited by 126 publications

(118 citation statements)

References 29 publications

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“…The use of mercury in these junctions is also similar to the Hg Á/Ag junctions described by Whitesides and coworkers [4,5] to the Hg Á/ SiO 2 Á/p-Si junctions of Cahen and coworkers [6] and to Hg Á/C junctions reported recently by McCreery and coworkers [7] An overview of the related research with scanning probe microscopy can be found in a recent report by Bard and co-workers [8]. In this report, in order to improve the stability of the junctions and reproducibility of the resulting I/V curves, we first characterize the structure of the alkanethiol monolayers on gold substrates by recording standard cyclic voltammetric current voltage curves in aqueous electrolytes of a redox probe.…”

Section: Introductionsupporting

confidence: 78%

Asymmetric electron transmission across asymmetric alkanethiol bilayer junctions

Galperin

Nitzan

Sęk

et al. 2003

Journal of Electroanalytical Chemistry

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Asymmetric I /V curves with respect to the polarity of the voltage bias were observed in the Hg Á/Au junctions containing bilayers of alkanethiols of different chain length. A larger current resulted when a negative bias was applied to the metal carrying a longer chain alkanethiol monolayer. This behavior is simulated using a single molecule junction model, within the frameworks of the extended Hü ckel (EH) model and the nonequilibrium Green's function formalism at the Hartree Fock level (NEGF-HF). Qualitative agreement with the experimental results with respect to the magnitude and sign of this asymmetry is obtained. On the basis of the NEGF-HF calculation, the origin of the effect is suggested to be the asymmetric behavior of the character of the junction highest occupied molecular orbital (HOMO) at opposite biases. This change of character leads to different effective barriers for electron transfer for opposite signs of the voltage drop across the junction. #

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Section: Introductionsupporting

confidence: 78%

Asymmetric electron transmission across asymmetric alkanethiol bilayer junctions

Galperin

Nitzan

Sęk

et al. 2003

Journal of Electroanalytical Chemistry

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“…In order to investigate if this range of barrier heights is realized in carbon/molecule devices, large area PPF/molecule/Cu molecular junctions were constructed from the structures in Fig. 2 using previously described techniques (15,(17)(18)(19). In all cases, the value of the attenuation factor (β) was measured by variation of the molecular layer thickness.…”

Section: Resultsmentioning

confidence: 99%

“…Although each method has certain advantages and disadvantages, it is clear that the entire system must be considered in order to delineate the main factors influencing molecular conduction. Whereas many groups employ thiolate-based self-assembled monolayers (SAMs) on metallic substrates as a base system, we have taken an alternative approach using carbon electrodes (6,(14)(15)(16)(17)(18)(19). The foundation of this paradigm is a flat carbon electrode composed of pyrolyzed photoresist films (PPF) with covalently bonded nanoscopic molecular layers deposited using the electrochemical reduction of diazonium reagents.…”

mentioning

confidence: 99%

Charge transport in molecular electronic junctions: Compression of the molecular tunnel barrier in the strong coupling regime

Sayed

Fereiro²,

Yan³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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139

253

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Molecular junctions are essentially modified electrodes familiar to electrochemists where the electrolyte is replaced by a conducting "contact." It is generally hypothesized that changing molecular structure will alter system energy levels leading to a change in the transport barrier. Here, we show the conductance of seven different aromatic molecules covalently bonded to carbon implies a modest range (<0.5 eV) in the observed transport barrier despite widely different free molecule HOMO energies (>2 eV range). These results are explained by considering the effect of bonding the molecule to the substrate. Upon bonding, electronic inductive effects modulate the energy levels of the system resulting in compression of the tunneling barrier. Modification of the molecule with donating or withdrawing groups modulate the molecular orbital energies and the contact energy level resulting in a leveling effect that compresses the tunneling barrier into a range much smaller than expected. Whereas the value of the tunneling barrier can be varied by using a different class of molecules (alkanes), using only aromatic structures results in a similar equilibrium value for the tunnel barrier for different structures resulting from partial charge transfer between the molecular layer and the substrate. Thus, the system does not obey the Schottky-Mott limit, and the interaction between the molecular layer and the substrate acts to influence the energy level alignment. These results indicate that the entire system must be considered to determine the impact of a variety of electronic factors that act to determine the tunnel barrier.energy alignment | molecular electronics | electronic coupling | charge transport | Fermi-level pinning T he conductance of electrical charge through and across molecular entities is the basis of molecular and organic electronics (1, 2). Understanding, controlling, and designing electronic circuits using organic molecules as components is a major goal of molecular electronics (3); however, it has been a challenge to identify all of the factors that govern the conductance of a molecular junction. Rather than being a simple property of the molecule itself, many circumstances contribute to the measured electronic properties of the junction. Some of the important features include the nature of the molecule-contact bonding (4), the properties of the contact materials (5, 6), the orientation of the molecules relative to the contacts (7), and the structure of the molecule (5,8,9). Although there is no general consensus on exactly how each of these features affects the conductance of the junction, it is generally agreed that the alignment of the molecular and contact energy levels is an important factor (10-13). The offset between the substrate Fermi energy (E f ) and the molecular orbital closest in energy to E f is often used to estimate charge transport barriers in the context of tunneling or charge injection models; however, it is increasingly clear that the situation is complex and that there is no simple meth...

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“…Graphitic carbons have many attractive characteristics, including ease-ofhandling, low-cost, high mechanical stability and good electrical conductivity. The material is readily available in a number of forms including high surface area felts and cloths suitable as supports for combinatorial chemistry [1,2], carbon powders useful for chromatography [3], glassy carbon (GC) [4], a convenient material for planar electrodes and very smooth films of pyrolysed photoresist [5] suitable for applications in molecular electronics [6,7,8]. Another advantage of graphitic carbon is that the surface can be easily modified by methods which give very stable molecular coatings, attached by strong C-C [9] or C-N covalent bonds.…”

Section: Introductionmentioning

confidence: 99%

Covalent modification of graphitic carbon substrates by non-electrochemical methods

Barrière

Downard

2008

J Solid State Electrochem

156

119

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Abstract:New methods for modifying graphitic carbon surfaces without electrochemical assistance, and without the deliberate formation of carbon surface oxygen functionalities, have emerged in the past decade. The approaches rely on spontaneous reactions of aryldiazonium salts, primary amines, ammonia and iodine azide at room temperature, chemical reduction of aryldiazonium salts, reactions of alkenes and alkynes at elevated temperatures, and photochemical reactions of alkenes, alkynes, azides and diazirines. This review describes the methodology and scope of these reactions at graphitic carbon materials (excluding carbon nanotubes), examines mechanistic possibilities and future prospects.

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Covalently Bonded Organic Monolayers on a Carbon Substrate: A New Paradigm for Molecular Electronics

Cited by 126 publications

References 29 publications

Asymmetric electron transmission across asymmetric alkanethiol bilayer junctions

Asymmetric electron transmission across asymmetric alkanethiol bilayer junctions

Charge transport in molecular electronic junctions: Compression of the molecular tunnel barrier in the strong coupling regime

Covalent modification of graphitic carbon substrates by non-electrochemical methods

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