Exceptional Single-Molecule Transport Properties of Ladder-Type Heteroacene Molecular Wires

Cai, Zhengxu; Lo, Wai-Yip; Zheng, Tianyue; Li, Lianwei; Zhang, Na; Hu, Yubing; Yu, Luping

doi:10.1021/jacs.6b05983

Cited by 86 publications

(80 citation statements)

References 36 publications

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“…In addition to expanding the molecular‐electronics toolbox with new design ideas for molecular termini and contacts, our results shed light on the mechanism of configuration transitions in thienyl‐based hemilabile ligands, showing that the fabrication of single‐molecule junctions doubles also as a valuable characterisation tool to probe metal–ligand interactions. Furthermore, (methylthio)thiophenes and thiophenethiols are widely used as molecular‐wire termini in molecular electronics, and our results unambiguously demonstrate that contact‐configuration changes must be taken into account when interpreting their conductance‐vs.‐electrode‐separation trajectories during a single‐entity break‐junction experiment.…”

Section: Resultssupporting

confidence: 69%

Hemilabile Ligands as Mechanosensitive Electrode Contacts for Molecular Electronics

et al. 2019

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Single‐molecule junctions that are sensitive to compression or elongation are an emerging class of nanoelectromechanical systems (NEMS). Although the molecule–electrode interface can be engineered to impart such functionality, most studies to date rely on poorly defined interactions. We focused on this issue by synthesizing molecular wires designed to have chemically defined hemilabile contacts based on (methylthio)thiophene moieties. We measured their conductance as a function of junction size and observed conductance changes of up to two orders of magnitude as junctions were compressed and stretched. Localised interactions between weakly coordinating thienyl sulfurs and the electrodes are responsible for the observed effect and allow reversible monodentate⇄bidentate contact transitions as the junction is modulated in size. We observed an up to ≈100‐fold sensitivity boost of the (methylthio)thiophene‐terminated molecular wire compared with its non‐hemilabile (methylthio)benzene counterpart and demonstrate a previously unexplored application of hemilabile ligands to molecular electronics.

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Section: Resultssupporting

confidence: 69%

Hemilabile Ligands as Mechanosensitive Electrode Contacts for Molecular Electronics

et al. 2019

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“…The second strategy involves the lowering of HOMO–LUMO gap by coupling of donor and acceptor moieties through π‐conjugated bridges . Employing the first strategy, Yu's group recently demonstrated the efficacy of locked ladder systems towards enhancing charge transport in molecular wires . Building upon their previous work, his group synthesized a series of ladder‐type thienoacene‐based molecular wires with 3, 5, 7, 9, and 11 rings in their backbone; these were further functionalized with thiol groups for direct assembly onto a gold surface (Figure ) .…”

Section: Enhancing Charge Transport Through Locked Ladder Systemsmentioning

confidence: 99%

Section: Enhancing Charge Transport Through Locked Ladder Systemsmentioning

confidence: 99%

“…Detailed conductance measurements revealed two conductance plateaus in the decay curves for MW‐S and MW‐Se, but only one conductance plateau in the decay curve for MW‐N. The high‐conductance plateaus for MW‐S and MW‐Se are around 10 −3 G 0 , while their low‐conductance plateaus are around 10 −4 G 0 , which is close to the conductance plateau observed for MW‐N and fused HA9 molecular wire described above . The high‐conductance plateau was assigned to the charge‐transport pathway between a thiol anchoring group and the central benzodiazole acceptor ring, while the low‐conductance plateau corresponds to the conducting pathway between the thiol anchoring groups.…”

Section: Enhancing Charge Transport Through Locked Ladder Systemsmentioning

confidence: 99%

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Molecular Design towards Controlling Charge Transport

Awais

Cai

Zhang

et al. 2018

Chemistry A European J

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Organic electronics generally deals with bulk, statistically averaged electrical properties of organic materials. Single-molecule electronic devices can then be viewed as linkers to these bulk properties. However, controlling charge transport in single-molecule systems still remains a formidable task and has prevented proliferation of these systems from research laboratories to household electronics. This Concept article provides a general overview of the recent advances made by our group in the field. We will describe several concepts in designing molecular functions towards controlling charge transport through molecular systems. It should be noted, however, that this Concept article is by no means comprehensive and readers should look elsewhere for a more comprehensive picture of molecular electronics.

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“…[1] Simple molecular electronic functional devices, such as molecular rectifiers, [2,3] molecular switches, [4,5] molecular wires [6,7] and molecular sensors [8][9][10] have been designed theoretically and synthesized experimentally on single-molecular scale. [1] Simple molecular electronic functional devices, such as molecular rectifiers, [2,3] molecular switches, [4,5] molecular wires [6,7] and molecular sensors [8][9][10] have been designed theoretically and synthesized experimentally on single-molecular scale.…”

Section: Introductionmentioning

confidence: 99%

Spin Logic Gates Operated by Protonation and Magnetism in Molecular Combinational Circuits

Zhao

Zou

Sun

et al. 2019

Advcd Theory and Sims

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The protonation and magnetism effects on the spin transport properties of benzo[b]phenazine (BPE) and bis(o-phenylenediamine) manganese (IV) complex (Mn-OPD) molecules in series and in parallel are theoretically investigated using density functional theory (DFT) combined with nonequilibrium Green's function method (NEGF). The spin-resolved currentvoltage curves show that the magnetic field mainly regulate the spin-polarized direction of current, and the protonation effect will significantly reduce the magnitude of spin-polarized current. Moreover, under two orthogonal inputs, the molecular combinational circuits can behave as AND and OR spin logic gates, suggesting the application potential of integrating logic operations for future spin-based nanoelectronics. In addition, we have observed the Fano resonance phenomenon in the parallel molecular junction, and the Fano resonance feature can be canceled by protonation effect. This work proposes a feasible way to construct a complex single-molecule spin logic gate device.

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Exceptional Single-Molecule Transport Properties of Ladder-Type Heteroacene Molecular Wires

Cited by 86 publications

References 36 publications

Hemilabile Ligands as Mechanosensitive Electrode Contacts for Molecular Electronics

Hemilabile Ligands as Mechanosensitive Electrode Contacts for Molecular Electronics

Molecular Design towards Controlling Charge Transport

Spin Logic Gates Operated by Protonation and Magnetism in Molecular Combinational Circuits

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