Electron transport and redox reactions in carbon-based molecular electronic junctions

McCreery, Richard L.; Wu, Jing; Kalakodimi, Rajendra Prasad

doi:10.1039/b601163m

Cited by 76 publications

(147 citation statements)

References 168 publications

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“…Whatever the origin of the hopping, it is observed much less frequently in SAMs than is tunneling because the typical lengths of the molecules investigated are seldom greater than $2 nm. [162,189,190] Extensive theoretical work has been reported concerning the tunneling/hopping transition, [154,[191][192][193][194][195][196][197] and earlier data on some organics [198][199][200][201] and DNA [202,203] have clearly revealed a length dependent transition between tunneling and hopping conduction. Recently, the transition was demonstrated in Au-molecule-Au junctions, where the electrical resistance of oligophenyleneimine (OPI) molecules of various lengths were measured with a conductive AFM tip (Fig.…”

Section: Thermally Activated Processesmentioning

confidence: 97%

Molecular Self‐Assembled Monolayers and Multilayers for Organic and Unconventional Inorganic Thin‐Film Transistor Applications

DiBenedetto¹,

Facchetti²,

Ratner³

et al. 2009

Advanced Materials

569

538

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Principal goals in organic thin‐film transistor (OTFT) gate dielectric research include achieving: (i) low gate leakage currents and good chemical/thermal stability, (ii) minimized interface trap state densities to maximize charge transport efficiency, (iii) compatibility with both p‐ and n‐ channel organic semiconductors, (iv) enhanced capacitance to lower OTFT operating voltages, and (v) efficient fabrication via solution‐phase processing methods. In this Review, we focus on a prominent class of alternative gate dielectric materials: self‐assembled monolayers (SAMs) and multilayers (SAMTs) of organic molecules having good insulating properties and large capacitance values, requisite properties for addressing these challenges. We first describe the formation and properties of SAMs on various surfaces (metals and oxides), followed by a discussion of fundamental factors governing charge transport through SAMs. The last section focuses on the roles that SAMs and SAMTs play in OTFTs, such as surface treatments, gate dielectrics, and finally as the semiconductor layer in ultra‐thin OTFTs.

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Section: Thermally Activated Processesmentioning

confidence: 97%

Molecular Self‐Assembled Monolayers and Multilayers for Organic and Unconventional Inorganic Thin‐Film Transistor Applications

DiBenedetto¹,

Facchetti²,

Ratner³

et al. 2009

Advanced Materials

569

538

View full text Add to dashboard Cite

show abstract

“…[10,65,66,81,84] Examples from three different laboratories where vapor deposition was carried out successfully onto covalently bonded molecular layers are shown in Figure 16 and 17. Figure 16 shows results for molecular junctions made using diazonium-derived aromatic molecular layers on carbon with e-beam-deposited Cu top contacts.…”

Section: Progress Reportmentioning

confidence: 99%

“…Changes in the oxidation state of molecules within junctions can accompany electron conduction and also result in the bistability important to memory devices. [10,14,15] As described in later sections, the concepts from these various disciplines are important for understanding the behavior and functions of molecular junctions, all of which are needed to meet key objectives in the field.…”

Section: Progress Reportmentioning

confidence: 99%

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

2009

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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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“…The original papers should be consulted for fabrication details and properties of PPF/molecule/metal molecular junctions. [19,[22][23][24][25][26] All current/voltage curves are presented as J (A cm 4), all between PPF and Cu contacts. As reported elsewhere, these PPF/molecule/Cu devices all show an activated region above~250 K, with Arrhenius slopes of 0.02-0.17 eV [22] .…”

Section: Examples Of Redox Reactions In Molecular Junctionsmentioning

confidence: 99%

Electron Transport and Redox Reactions in Molecular Electronic Junctions

McCreery

2009

ChemPhysChem

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Electron transport through single molecules or collections of molecules oriented in parallel can occur by several mechanisms, including coherent tunneling, activated transfer between potential wells, various "hopping" modes, etc. Given suitable energy levels and sufficiently long charge transport times, reduction or oxidation with accompanying nuclear reorganization can occur to generate "polarons", that is, localized redox centers in the molecule or monolayer. Redox events in molecular junctions are amenable to spectroscopic monitoring in working devices, and can have major effects on the electronic behavior of the junction. Several examples are presented, along with a possible application to molecular memory.

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Electron transport and redox reactions in carbon-based molecular electronic junctions

Cited by 76 publications

References 168 publications

Molecular Self‐Assembled Monolayers and Multilayers for Organic and Unconventional Inorganic Thin‐Film Transistor Applications

Molecular Self‐Assembled Monolayers and Multilayers for Organic and Unconventional Inorganic Thin‐Film Transistor Applications

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

Electron Transport and Redox Reactions in Molecular Electronic Junctions

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