Expanded Radialenes with Bicyclo[4.3.1]decatriene Units: New Precursors to Cyclo[<i>n</i>]carbons

Tobe, Yoshito; Umeda, Rui; Iwasa, Naruhito; Sonoda, Motohiro

doi:10.1002/chem.200305051

Cited by 55 publications

(70 citation statements)

References 76 publications

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“…4). [26,[97][98][99][100][101] Compounds 14-16 possess persilylated C 40 (diameter excluding the silyl groups: $17 Å ), C 50 (19 Å ), and C 60 cores (22 Å ), respectively, and are high-melting (>220 8C), stable, yellow solids. [85,96] Macrocyclic cross-conjugation is not very efficient and therefore, the end-absorption of all three chromophores appears at nearly the same wavelength, below 500 nm.…”

Section: Expanded Radialenes and Radiaannulenesmentioning

confidence: 99%

“…Compound 20 (only one diastereoisomer is shown) is a precursor to cyclo-C 30 , and the corresponding molecular anion peak C 30 À , formed by stepwise loss of indane fragments, is observed in the negative-mode laser-desorption time-of-flight (LDÀTOF) mass spectrum. [26] The extended [9] radialene 21 forms a complex with a Ag þ ion, which most probably is incorporated in its inner cavity. The periphery of 21 contains sterically overcrowded regions and rotation of the chlorobenzene rings is slow on the NMR time scale.…”

Section: Expanded Radialenes and Radiaannulenesmentioning

confidence: 99%

“…[21] Since the late 1980s, elegant protocols to prepare cyclocarbons starting from defined macrocyclic dehydroannulene or expanded radialene precursors were developed but their synthesis only succeeded in the gas phase and bulk quantities have not been isolated, so far. [22][23][24][25][26] 2D carbon networks, different from graphite, as well as 3D carbon networks were proposed since the late 1980s, [23,[27][28][29] stimulated by the discovery that fullerenes are stable carbon allotropes. However, structural chemical imagination clearly exceeds current synthetic availability and hardly any of the proposed networks have become the target of serious preparative work, with two exceptions: graphyne (2) and graphdiyne (3, Fig.…”

Section: Introductionmentioning

confidence: 99%

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All‐Carbon Scaffolds by Rational Design

2010

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The search for new molecular and regular polymeric allotropes of carbon has greatly stimulated the preparation and investigation of pi-conjugated acetylenic macrocycles, which often represent substructures of proposed 2D carbon networks. Perethynylated dehydroannulenes, expanded radialenes, and radiaannulenes with large, multi-nanometer-sized all-carbon cores are potent electron acceptors, and their optoelectronic as well as stability and solubility properties are greatly enhanced by peripheral donor substitution. Acetylenic scaffolding into three dimensions has generated an expanded cubane with a C(56) core, the first representative of a new class of "platonic" objects. Exceptional chiroptical properties displayed by enantiomerically pure alleno-acetylenic, shape-persistent macrocycles promise fascinating perspectives for the development of molecular and supramolecular chiroptical materials.

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Section: Expanded Radialenes and Radiaannulenesmentioning

confidence: 99%

Section: Expanded Radialenes and Radiaannulenesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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All‐Carbon Scaffolds by Rational Design

2010

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“…Shape-persistent, conjugated macrocycles with all-carbon skeletons are of interest to many research groups [53][54][55][56][57][58][59][60][61][62][63][64]. In our research aimed at producing large all-carbon sheets [7], we have become interested in three classes of macrocycles, perethynylated dehydroannulenes [65], perethynylated expanded radialenes [66], and perethynylated radiaannulenes [68].…”

Section: Large All-carbon Sheets With Peripheral Donor Groupsmentioning

confidence: 99%

“…In 1993, we had reported the first examples of the expanded radialenes [71] and had since then continued investigating the opto-electronic properties of these novel macrocyclic chromophores [72] (for other work, see [54,55]). In continuation of this work, three series of perethynylated expanded [n]radialenes (n = 3, 4, 6, 8) 8a-c, 9a-d, and 10a-d with differently functionalized peripheral phenyl rings were prepared and subjected to comprehensive physical-organic study (Fig.…”

Section: F Diederichmentioning

confidence: 99%

Advanced opto-electronics materials by fullerene and acetylene scaffolding

Diederich

2005

Pure and Applied Chemistry

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Functional π-systems with unusual opto-electronic properties are intensively investigated from both fundamental research and technological application viewpoints. This article reports on novel π-conjugated systems obtained by acetylenic and fullerene scaffolding. Linearly conjugated acetylenic nanorods, consisting of monodisperse poly(triacetylene) (PTA) oligomers and extending up to 18 nm length, were prepared to investigate the limits of effective conjugation and to explore at which length a monodisperse oligomer reaches the properties of an infinite polydisperse polymer. With the cyanoethynylethenes (CEEs), a powerful new class of electron acceptors is introduced that undergo intense intramolecular charge-transfer (CT) interactions with appended donors. Macrocyclic scaffolds with unusual opto-electronic properties are perethynylated dehydroannulenes, expanded radialenes, and radiaannulenes bearing peripheral dialkylanilino donor groups. Extended porphyrin-fullerene conjugates are investigated for their novel photophysical and efficient multicharge storage properties. Self-assembly of fullerenes and porphyrins, governed by weak interactions between the two components, leads to unprecedented nanopatterned surfaces that are investigated by scanning tunneling microscopy (STM).

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Polyynes Via Alkylidene Carbenes and Carbenoids

Eisler

Tykwinski

2004

Acetylene Chemistry

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of detail it also surveys some of the unique properties displayed by these newly obtained materials, including solid-state structure and stability, and the linear and nonlinear optical properties of conjugated polyynes. Alkylidene Carbene and Carbenoid SpeciesAlkylidene carbenes/carbenoids (1 and 2) are reactive intermediates capable of undergoing several distinct reactions (Scheme 7.1) [13]. Carbenoid 1 and alkylidene carbene 2 are distinguished by the association of the carbon in 1 with a metal and a halogen (or another leaving group), while the free carbene 2 has no such ties. The two extremes can vary greatly in reactivity. Within this range of reactivity, solvent, b-substituent, and temperature can all affect the reaction outcome. For carbenoid intermediates, both the metal and the leaving group can also greatly influence the reaction [13e]. 261 7.3 Alkyne Formation from Carbenes and Carbenoids R R' 17 70% 16a X = ZnX 16b X = Li -20 ˚C to rt Et 2 O Equation 7-1 263 7.3 Alkyne Formation from Carbenes and Carbenoids H Cl BuLi, THF -90 ˚C 18 19 77% Equation 7-2 CH 3 H Cl CH 3 BuLi THF/Et 2 O > -70 ˚C 20 21 65% Equation 7-3 H Br Br Br t-BuOK ∆ 23 24 22 -40 ˚C to 0 ˚C PhLi, benzene/ether Equation 7-4 265 7.3 Alkyne Formation from Carbenes and Carbenoids Cl Cl Cl S Cl S S S S S S S BuLi, THF -90 to 0 ˚C 31 32 30% Equation 7-6 a Dibromoolefin formation as in Scheme 7.5.

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Expanded Radialenes with Bicyclo[4.3.1]decatriene Units: New Precursors to Cyclo[n]carbons

Cited by 55 publications

References 76 publications

All‐Carbon Scaffolds by Rational Design

All‐Carbon Scaffolds by Rational Design

Advanced opto-electronics materials by fullerene and acetylene scaffolding

Polyynes Via Alkylidene Carbenes and Carbenoids

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