Effect of Anchoring Groups on Single-Molecule Conductance:  Comparative Study of Thiol-, Amine-, and Carboxylic-Acid-Terminated Molecules

Chen, Fang; Li, Xiulan; Hihath, Joshua; Huang, Zhifeng; Tao, Nongjian

doi:10.1021/ja065864k

Cited by 722 publications

(1,045 citation statements)

References 35 publications

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“…Each consists of 13 aromatic rings, and has two terminal groups that can bind to electrodes for electrical contacts. Th e terminal groups in 1 are amines, which have been shown to provide good contact to gold electrodes 10,11 . 2 , in contrast, has two thiols as terminal groups, which are separated from the coronene core by additional spacers.…”

Section: Resultsmentioning

confidence: 99%

Gate-controlled electron transport in coronenes as a bottom-up approach towards graphene transistors

et al. 2010

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Graphene is considered to be a large aromatic molecule, the limiting case of the family of polycyclic aromatic hydrocarbons. This fascinating two-dimensional material has many potential applications, including fi eld effect transistors (FETs). However, the graphene sheets in these devices have irregular shapes and variable sizes, and contain various impurities and defects, which are undesirable for applications. Moreover, the bandgap of graphene is zero and, consequently, the on / off ratios of graphene FETs are small, making it diffi cult to build logic circuits. To overcome these diffi culties, we report here a bottom-up attempt to fabricate nanoscale graphene FETs. We synthesize structurally well-defi ned coronene molecules (consisting of 13 benzene rings) terminated with linker groups, bridge each molecule to source and drain electrodes through the linkers, measure conductance and demonstrate the FET behaviour of the molecule.

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Section: Resultsmentioning

confidence: 99%

Gate-controlled electron transport in coronenes as a bottom-up approach towards graphene transistors

et al. 2010

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“…Reported temperature dependence of transport varies from none [55,172,174,175] to positive (i.e., thermal activation). [34,55,96] In MIM junctions, a pseudo-metallic temperature response is generally attributed to conductance via metallic filaments penetrating the monolayer.…”

Section: Quasi-metallic Temperature Behavior For Monolayer-limited Cumentioning

confidence: 99%

Molecules on Si: Electronics with Chemistry

et al. 2009

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Basic scientific interest in using a semiconducting electrode in molecule‐based electronics arises from the rich electrostatic landscape presented by semiconductor interfaces. Technological interest rests on the promise that combining existing semiconductor (primarily Si) electronics with (mostly organic) molecules will result in a whole that is larger than the sum of its parts. Such a hybrid approach appears presently particularly relevant for sensors and photovoltaics. Semiconductors, especially Si, present an important experimental test‐bed for assessing electronic transport behavior of molecules, because they allow varying the critical interface energetics without, to a first approximation, altering the interfacial chemistry. To investigate semiconductor‐molecule electronics we need reproducible, high‐yield preparations of samples that allow reliable and reproducible data collection. Only in that way can we explore how the molecule/electrode interfaces affect or even dictate charge transport, which may then provide a basis for models with predictive power.To consider these issues and questions we will, in this Progress Report, review junctions based on direct bonding of molecules to oxide‐free Si. describe the possible charge transport mechanisms across such interfaces and evaluate in how far they can be quantified. investigate to what extent imperfections in the monolayer are important for transport across the monolayer. revisit the concept of energy levels in such hybrid systems.

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“…This large dependence was attributed to different electronic coupling efficiencies provided by the different anchoring groups. [113] Hence noble metals such as gold in connection with sulfur as anchor group are ideal candidates for the immobilization of organic molecules to a metal. Based on the formed covalent bond a high stability of the molecular layer with the substrate is guaranteed.…”

Section: Covalent Linkage To Goldmentioning

confidence: 99%

Shape‐Switchable Azo‐Macrocycles

et al. 2009

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The synthesis of four shape‐switchable macrocycles comprising different peripheral substituents is described. The macrocycles 1–4 consist of m‐terphenyl semicircles interlinked by two azo joints. These macrocycles were assembled from nitro‐functionalized m‐terphenyl moieties through reductive dimerization. The semicircles were assembled through Suzuki cross‐coupling reactions. The molecular weights of the macrocycles were determined by vapour pressure osmometry, because mass spectrometry failed in the cases of 2 and 3. The E → Z photoisomerization reactions were analysed by UV/Vis spectroscopy complemented by 1H NMR studies. A very slow thermal back‐reaction indicated considerable stabilization of the Z isomer. The reduced efficiency of the thermal back‐reaction probably arises from the reduced degree of freedom due to the mechanical interlinking of the two azo groups. The photostationary state consisted of all‐Z (85 %) and all‐E isomers (15 %). The E → Z transformation induced by irradiation displayed simple exponential kinetics, which indicates pairwise switching of the two azo groups in a macrocycle, at least on the timescale under investigation. (© Wiley‐VCH Verlag GmbH & Co. KGaA, 69451 Weinheim, Germany, 2009)

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Effect of Anchoring Groups on Single-Molecule Conductance: Comparative Study of Thiol-, Amine-, and Carboxylic-Acid-Terminated Molecules

Cited by 722 publications

References 35 publications

Gate-controlled electron transport in coronenes as a bottom-up approach towards graphene transistors

Gate-controlled electron transport in coronenes as a bottom-up approach towards graphene transistors

Molecules on Si: Electronics with Chemistry

Shape‐Switchable Azo‐Macrocycles

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