The single-molecule electrical conductance of a rotaxane-hexayne supramolecular assembly

Milan, David C.; Krempe, Maximilian; Ismael, Ali K.; Movsisyan, Levon D.; Franz, Michael; Grace, Iain; Brooke, Richard J.; Schwarzacher, Walther; Higgins, Simon J.; Anderson, Harry L.; Lambert, Colin J.; Tykwinski, Rik R.; Nichols, Richard J.

doi:10.1039/c6nr06355a

Cited by 51 publications

(61 citation statements)

References 53 publications

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“…Adams and co-workers investigated reactions of ferrocene end-capped polyynes with Os 3 (CO) 11 (MeCN) and H 2 Os 3 (CO) 10 . Adams and co-workers investigated reactions of ferrocene end-capped polyynes with Os 3 (CO) 11 (MeCN) and H 2 Os 3 (CO) 10 .…”

Section: Adducts With Metal Carbonylsmentioning

confidence: 99%

“…Tetrayne 246 in reaction with both osmium reagents gives complex mixture of products. [108] If H 2 Os 3 (CO) 10 was used instead of Os 3 (CO) 11 (MeCN) in reaction with tetrayne 246 then products of single (252, 253) addition with simultaneous reduction were isolated. [110] Hexayne 238 gave product of twofold addition (251) in reaction with the same osmium carbonyl.…”

Section: Adducts With Metal Carbonylsmentioning

confidence: 99%

“…[110] Hexayne 238 gave product of twofold addition (251) in reaction with the same osmium carbonyl. Bruce and co-workers also reported an adduct 255 which was a result of reaction of unsymmetrical triyne 177 with Os 3 (CO) 11 (MeCN). [111] It was possible to next transform compound 253 into the product of double addition 254.…”

Section: Adducts With Metal Carbonylsmentioning

confidence: 99%

“…[6] Polyynes may be regarded as model compounds of hypothetical linear allotropic form of carbon -carbyne. Polyynes also possess a remarkable application potential as molecular wires and switches in nanoelectronics, [7][8][9][10][11] as materials for optoelectronics due to their nonlinear optical response, [12][13][14][15][16][17][18] as precursors of conducting polymers [19,20] or even in live-cells imaging and sorting. Polyynes also possess a remarkable application potential as molecular wires and switches in nanoelectronics, [7][8][9][10][11] as materials for optoelectronics due to their nonlinear optical response, [12][13][14][15][16][17][18] as precursors of conducting polymers [19,20] or even in live-cells imaging and sorting.…”

Section: Introductionmentioning

confidence: 99%

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Reactivity of Polyynes: Complex Molecules from Simple Carbon Rods

2019

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Polyynes are linear carbon rods that may be regarded as models of carbyne – still elusive linear allotropic form of carbon. This microreview addresses the use of polyynes as synthetic precursors of complex organic and organometallic compounds. Application of such unusual molecules as starting materials for various chemical transformations leads to products which often are not easily accessible using “traditional“ approaches. Polyynes may for instance be used in the synthesis of molecular wires, materials possessing high nonlinear optical response, complex donor–acceptor systems, solvatochromic fluorescent dyes or natural products. The most significant challenge here is to control the regioselectivity of a transformation of such linear sp‐hybridized carbon chains. The impact of steric and electronic properties of reagents on the reaction pattern is hence highly important and will be discussed. Moreover, the transformations of end‐groups will also be addressed since their reactivity might very often be different than that of acetylenes.

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Section: Adducts With Metal Carbonylsmentioning

confidence: 99%

Section: Adducts With Metal Carbonylsmentioning

confidence: 99%

Section: Adducts With Metal Carbonylsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Reactivity of Polyynes: Complex Molecules from Simple Carbon Rods

2019

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“…Linearly conjugated π‐electron systems such as polyynes or polyarylenes are often considered as models for the “molecular wires“ which can conduct electrons along the π‐system . On the other hand, they can also “wire” two chromophores at the termini.…”

Section: Introductionmentioning

confidence: 99%

Molecular Wires with Controllable π‐Delocalization Incorporating Redox‐Triggered π‐Conjugated Switching Units

et al. 2018

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A perfluorobiphenyl‐2,2′‐diyl dication and its corresponding dihydrophenanthrene‐type electron donor are interconvertible upon two‐electron transfer. Redox‐triggered C−C bond‐formation/cleavage caused a drastic change in the torsion angle of the biphenyl unit. Thus, π‐delocalization ON/OFF switching was observed as a change in the UV absorption upon electrolysis of the linearly extended analogue with two phenylethynyl groups. A further extended π‐system with a molecular length of ca. 3.5 nm, which has two switching units, was synthesized. Spectroelectrograms as well as voltammetric analyses showed that the two units act nearly simultaneously because of the very small inter‐unit electrostatic repulsion in the tetracationic state. Thus, the present pair is a promising candidate as a switching unit for “molecular wires” with controllable π‐delocalization, in which a higher ON/OFF ratio of delocalization could be realized by incorporating multiple switching units.

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Metal Complexes and Clusters in Single‐Molecule Electronics

Vezzoli

2021

Encyclopedia of Inorganic and Bioinorganic Chemistry

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Single‐molecule electronics has evolved significantly in the past two decades. The first studies that focussed on simple, wire‐like organic compounds have been useful to establish the mechanism of charge transport, but the chemical complexity of the molecular component has been rapidly increased to allow the fabrication of functional devices such as switches and transistors. Organometallic compounds feature prominently in molecular electronics because as they offer, for instance, a straightforward way to impart redox activity and to control on the HOMO–LUMO gap, but they can also be used to study and exploit phenomena unique to the nanoscale world, such as quantum interference and Coulomb blockade effects. This article will present progress in the use of mono‐ and polynuclear (cluster) organometallic molecular wires in single‐molecule junctions, highlighting the breakthrough studies that advanced our understanding of nanoscale charge transport phenomena.

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The single-molecule electrical conductance of a rotaxane-hexayne supramolecular assembly

Cited by 51 publications

References 53 publications

Reactivity of Polyynes: Complex Molecules from Simple Carbon Rods

Reactivity of Polyynes: Complex Molecules from Simple Carbon Rods

Molecular Wires with Controllable π‐Delocalization Incorporating Redox‐Triggered π‐Conjugated Switching Units

Metal Complexes and Clusters in Single‐Molecule Electronics

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