Phenyl Shifts in Substituted Arenes via <i>Ipso</i> Arenium Ions

Ajaz, Aida; McLaughlin, Erin; Skraba, Sarah L.; Thamatam, Rajesh; Johnson, Richard P.

doi:10.1021/jo301848g

Cited by 54 publications

(50 citation statements)

References 117 publications

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“…Rathore and co-workers have demonstrated that ortho-terphenyl derivatives such as 7 undergo efficient Scholl cyclizations in the presence of DDQ/MeSO 3 Ht hrough the generation of radical cations such as 7C + (Figure 4). [6f] Consistent with the reported results for 7, [6f] cyclization or aryl migration [15] was not observed for 3 in acidic media using MeSO 3 H, implying that it should be unlikely that the cyclization of 3 proceeds by the arenium ion pathway.…”

supporting

confidence: 83%

Unsymmetric Twofold Scholl Cyclization of a 5,11‐Dinaphthyltetracene: Selective Formation of Pentagonal and Hexagonal Rings via Dicationic Intermediates

Chaolumen¹,

Murata

Wakamiya³

et al. 2017

Angew Chem Int Ed

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Even though the Scholl reaction is one of the most powerful processes for the synthesis of polycyclic aromatic hydrocarbons (PAHs), its mechanism still remains a subject of discussion. Herein, we report a unique twofold Scholl cyclization of a 5,11-dinaphthyltetracene. Single-crystal X-ray diffraction analysis of the cyclization product revealed that unsymmetric cyclizations of the two naphthyl groups resulted in the formation of fully unsaturated pentagonal and hexagonal rings. The thus obtained product exhibits a twisted π-surface and an absorption band that reaches up to 950 nm. A combined experimental and theoretical study showed that such unsymmetric Scholl cyclizations can be rationalized in terms of a mechanism that involves dicationic intermediates, which stands in contrast to previously reported pathways based on radical cations and arenium ions.

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supporting

confidence: 83%

Unsymmetric Twofold Scholl Cyclization of a 5,11‐Dinaphthyltetracene: Selective Formation of Pentagonal and Hexagonal Rings via Dicationic Intermediates

Chaolumen¹,

Murata

Wakamiya³

et al. 2017

Angew Chem Int Ed

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“…Many reports highlighted the importance of temperature and/or the presence of acid to catalyze the process [18][19][20][21][22]. In present case, the pyridine-2-carboxaldehyde (99 %) contains 0.5 % of the free acid and it is possibly the source of H + that catalyze the isomerization of the methyl group (steps 1, 2 and 3 in Scheme-II).…”

Section: Resultsmentioning

confidence: 86%

“…Isomerization of alkyl and aryl groups in arene rings has been reported in literatures [18][19][20][21] and such reaction has been used in many industrial processes including the conversion of mixed xylene to p-xylene [22]. Many reports highlighted the importance of temperature and/or the presence of acid to catalyze the process [18][19][20][21][22].…”

Section: Resultsmentioning

confidence: 99%

Synthesis of Novel Pyridyl-Based Schiff Base and Its Coordination Behaviour with Ruthenium(II) and Zinc(II)

Al-Rashdi¹,

Eltayeb²,

Al-Khathami³

et al. 2017

Asian J. Chem.

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High reactivity of the Schiff base product of p-toluidine with pyridine-2-carboxaldehyde was observed, leading to methyl group isomerization (immigration) to ortho-position followed by the dimerization reaction to form biphenyl system. This compound was identified and characterized using IR, ESI MS and NMR spectroscopic methods and its structure confirmed by XRD single crystal. The coordination behaviour of the Schiff base was examined using ruthenium(II) and zinc(II). Two metal complexes were only isolated and identified by Xray crystallography for ruthenium(II) and zinc(II). The coordination behaviour of both metals differs significantly, although both of them promote the oxidation reaction on one of the azomethine bond.

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“…Details of these systems can be found in [1,3,4,8,10,13,14,16,17]. In what follows, we simply refer to them as A, B, C, D, E, and F. Similarly, our discussion in Section 3 implies that ( ) ( ).…”

Section: Comparison With Physical Propertiesmentioning

confidence: 99%

Labelling and Comparison of Isomeric Tree-Like Polyphenyl Systems

Williford

Collins

Landge

et al. 2015

Jour. Math. Sci. Adv. Appl.

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Tree-like polyphenyl systems form an important class of compounds in chemistry, in particular material science and polymers. The importance can be seen in LEDs, transmitters, and electronics. In recent years, many extremal results regarding such systems under specific constraints have been reported.More specifically are the sub-categories of such systems with extremal Wiener indices. In this article, we provide a labelling of the vertices on each hexagon (i.e., the corresponding benzene ring), which facilitates the illustration of a treelike polyphenyl system with its corresponding tree structure. This approach helps to characterize the extremal tree-like polyphenyl systems with respect to the Wiener index and compare such systems in general within isometric molecules and between molecules of different underlying tree structures. The results can be used to order these systems, which will aid in predicting the physical properties of compounds. We also briefly examined tree-like polyphenyl systems that resulted from different tree structures.

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Phenyl Shifts in Substituted Arenes via Ipso Arenium Ions

Cited by 54 publications

References 117 publications

Unsymmetric Twofold Scholl Cyclization of a 5,11‐Dinaphthyltetracene: Selective Formation of Pentagonal and Hexagonal Rings via Dicationic Intermediates

Unsymmetric Twofold Scholl Cyclization of a 5,11‐Dinaphthyltetracene: Selective Formation of Pentagonal and Hexagonal Rings via Dicationic Intermediates

Synthesis of Novel Pyridyl-Based Schiff Base and Its Coordination Behaviour with Ruthenium(II) and Zinc(II)

Labelling and Comparison of Isomeric Tree-Like Polyphenyl Systems

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