Exploration of Nano‐Saturns: A Spectacular Sphere–Ring Supramolecular System

Toyota, Shinji; Tsurumaki, Eiji

doi:10.1002/chem.201900039

Cited by 51 publications

(50 citation statements)

References 166 publications

(119 reference statements)

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“…To provide a suitable context for the association constants presented above, recent work on “saturn complexes” based on unstrained, disc‐shaped macrocycles deserves a mention, despite technically being beyond the scope of this Minireview. As a consequence of the smaller surfaces involved in noncovalent interactions, the association constants for these complexes with C 60 ( 11 ⊃C 60 K A =2300 m −1 , toluene; 12 ⊃C 60 K A =580 m −1 , toluene) are three to four orders of magnitude lower than those for the [ n ]CPPs .…”

Section: Host–guest Chemistrymentioning

confidence: 99%

“…The key proposal of this study, which included several [ n ]CPP and [ n ]CPPA fullerene complexes as examples, is that collective charge fluctuations are responsible for the interactions in nanohoop/fullerene complexes and that only computational approaches which take this into account are suited to provide accurate predictions (Figure b). Finally, two recent articles cover theoretical aspects of the interaction of fullerenes with belt‐shaped compounds such as the “belt”‐shaped [ n ]CPPs and “disc”‐shaped compounds that give rise to “saturn” complexes …”

Section: Host–guest Chemistrymentioning

confidence: 99%

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The Supramolecular Chemistry of Strained Carbon Nanohoops

2019

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Since 1996, a growing number of strained macrocycles, comprising only sp2‐ or sp‐hybridized carbon atoms within the ring, have become synthetically accessible, with the [n]cycloparaphenyleneacetylenes (CPPAs) and the [n]cycloparaphenylenes (CPPs) being the most prominent examples. Now that robust and relatively general synthetic routes toward a diverse range of nanohoop structures have become available, the research focus is beginning to shift towards the exploration of their properties and applications. From a supramolecular chemistry perspective, these macrocycles offer unique opportunities as a result of their near‐perfect circular shape, the unusually high degree of shape‐persistence, and the presence of both convex and concave π‐faces. In this Minireview, we give an overview on the use of strained carbon‐rich nanohoops in host–guest chemistry, the preparation of mechanically interlocked architectures, and crystal engineering.

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Section: Host–guest Chemistrymentioning

confidence: 99%

Section: Host–guest Chemistrymentioning

confidence: 99%

The Supramolecular Chemistry of Strained Carbon Nanohoops

2019

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“…Um einen geeigneten Kontext für die oben vorgestellten Assoziationskonstanten zu geben, sind jüngere Arbeit an “Saturn‐Komplexen” auf der Grundlage von ungespannten, scheibenförmigen Makrozyklen zu erwähnen, obwohl sie technisch gesehen nicht mehr in den Rahmen dieses Kurzaufsatzes passen. Aufgrund der kleineren Oberfläche, die an nicht‐kovalenten Wechselwirkungen beteiligt ist, sind die Assoziationskonstanten für diese Komplexe mit C 60 ( 11 ⊃C 60 K A =2300 m −1 , Toluol; 12 ⊃C 60 K A =580 m −1 , Toluol) drei bis vier Größenordnungen niedriger als bei den [ n ]CPPs .…”

Section: Wirt‐gast‐chemieunclassified

“…Die zentrale Behauptung dieser Studie, die mehrere [ n ]CPP ‐ und [ n ]CPPA ‐Fullerenkomplexe als Beispiele umfasste, ist, dass kollektive Ladungsschwankungen für die Wechselwirkungen in Nanoreifen/Fulleren‐Komplexen verantwortlich sind und dass sich nur solche Rechenansätze für genaue Vorhersagen eignen, die dies berücksichtigen (Abbildung b). Schließlich behandeln zwei neuere Artikel theoretische Aspekte der Wechselwirkung von Fullerenen mit Verbindungen wie den “gürtelförmigen” [ n ]CPPs und “scheibenförmigen” Verbindungen, die in “Saturn‐Komplexen” vorliegen …”

Section: Wirt‐gast‐chemieunclassified

Supramolekulare Chemie von gespannten Kohlenstoffnanoreifen

Delius

2019

Angewandte Chemie

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Seit 1996 ist eine stetig wachsende Anzahl von hoch gespannten Makrozyklen präparativ zugänglich geworden, die lediglich sp2‐ oder sp‐hybridisierte Kohlenstoffatome im Ring enthalten, wobei [n]Cycloparaphenylenacetylene (CPPAs) und [n]Cycloparaphenylene (CPPs) die wichtigsten Beispiele dieser Klasse darstellen. Nachdem nun robuste und relativ allgemeine Synthesewege zu einer Vielzahl von Nanoreifen‐Strukturen zur Verfügung stehen, beginnt sich der Forschungsschwerpunkt auf die Erforschung ihrer Eigenschaften und Anwendungen zu verlagern. Aus Sicht der supramolekularen Chemie bieten diese Makrozyklen wegen ihrer nahezu perfekten Kreisform, der ungewöhnlich hohen Formstabilität und der Gegenwart von konvexen und konkaven π‐Flächen einzigartige Möglichkeiten. In diesem Kurzaufsatz besprechen wir den Einsatz von gespannten kohlenstoffreichen Nanoreifen in der Wirt‐Gast‐Chemie, der Herstellung von mechanisch verzahnten Architekturen und dem definierten Kristalldesign.

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“…Highly reactive C 59 NC radicals can be shielded by nesting them in carbon nanobelts consisting of single phenyl units connected in para position-cycloparaphenylenes (CPPs). [25][26][27][28][29][30][31] Our approach takes advantage of 1) the 1.4 nm cavity of [10]CPP, resembling the inner space of carbon nanotubes favoring p-p host-guest interactions,t oa ccommodate aC 59 NC radical (Figure 1a), 2) the diminished environmental exposure of the radical resulting from the favorable orientation of the CPPs close to the exposed radical, and 3) the well-established chemistry of C 59 NC,w hich prevents chemical addition to 1,4substituted phenylenes because of steric hindrance. [25][26][27][28][29][30][31] Our approach takes advantage of 1) the 1.4 nm cavity of [10]CPP, resembling the inner space of carbon nanotubes favoring p-p host-guest interactions,t oa ccommodate aC 59 NC radical (Figure 1a), 2) the diminished environmental exposure of the radical resulting from the favorable orientation of the CPPs close to the exposed radical, and 3) the well-established chemistry of C 59 NC,w hich prevents chemical addition to 1,4substituted phenylenes because of steric hindrance.…”

Section: Introductionmentioning

confidence: 99%

A Long‐Lived Azafullerenyl Radical Stabilized by Supramolecular Shielding with a [10]Cycloparaphenylene

et al. 2019

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Am ajor handicap towards the exploitation of radicals is their inherent instability.I nt he paramagnetic azafullerenyl radical C 59 NC,t he unpaired electron is strongly localized next to the nitrogen atom, which induces dimerization to diamagnetic bis(azafullerene), (C 59 N) 2 .C onventional stabilization by introducing steric hindrance around the radical is inapplicable here because of the concave fullerene geometry. Instead, we developed an innovative radical shielding approach based on supramolecular complexation, exploiting the protection offered by a[ 10]cycloparaphenylene ([10]CPP) nanobelt encircling the C 59 NC radical. Photoinduced radical generation is increased by af actor of 300. The EPR signal showing characteristic 14 Nh yperfine splitting of C 59 NC& [10]CPP was traced even after several weeks,w hichc orresponds to alifetime increase of > 10 8 .The proposed approach can be generalized by tuning the diameter of the employed nanobelts,opening new avenues for the design and exploitation of radical fullerenes.

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Exploration of Nano‐Saturns: A Spectacular Sphere–Ring Supramolecular System

Cited by 51 publications

References 166 publications

The Supramolecular Chemistry of Strained Carbon Nanohoops

The Supramolecular Chemistry of Strained Carbon Nanohoops

Supramolekulare Chemie von gespannten Kohlenstoffnanoreifen

A Long‐Lived Azafullerenyl Radical Stabilized by Supramolecular Shielding with a [10]Cycloparaphenylene

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