Trends in Inversion Barriers IV. The Group 15 Analogous of Pyrrole

Pelzer, Silke; Wichmann, Karin; Wesendrup, Ralf; Schwerdtfeger, Peter

doi:10.1021/jp0203494

Cited by 47 publications

(36 citation statements)

References 38 publications

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“…Here the phospholide 112 is reacted with carbon dioxide, presumably to give first a phosphole-1-carboxylate (113), in which it appears that the carboxylate moiety acted as a migrating group. An important feature of 113 is that there are trimethylsilyl groups present at the 2,5-positions; they play a useful role, since the silyl groups can be transferred to the carboxylate ions formed at these positions to generate a new phospholide (114).…”

Section: Reactions At the Phosphole Double Bonds And Syntheses Based mentioning

confidence: 99%

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The Continuing Development of the Chemistry of Phospholes

Quin¹

2006

COC

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The last five years have seen many advances in the chemistry of phospholes. Motivating much of the work has been the potential for discovering valuable applications of phospholes, especially as ligands in metal coordination compounds designed for use as homogeneous catalysts, and in the field of electro-optical substances. This review covers the research in the synthesis, properties and applications of phospholes that has been published since the last comprehensive review by the author in 1999. While prepared for the specialist, the review is designed to introduce some of the aspects of phosphole chemistry to the general reader.

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Section: Reactions At the Phosphole Double Bonds And Syntheses Based mentioning

confidence: 99%

“…Related to the previous topic are theoretical studies on the magnitude of the pyramidal inversion barrier [102,113].…”

Section: Computational and Theoretical Studies In Phosphole Chemistrymentioning

confidence: 99%

The Continuing Development of the Chemistry of Phospholes

Quin¹

2006

COC

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“…The NICS results did attribute slight aromaticity to arsole; the NICS(0) and NICS(1) values for arsole were found to be 26% and 44% of the corresponding pyrrole values, respectively. In a recent paper by Pelzer et al [19], another geometry based descriptor, the Julg index [20], was calculated. In a recent paper by Pelzer et al [19], another geometry based descriptor, the Julg index [20], was calculated.…”

Section: Introductionmentioning

confidence: 99%

Arsole Aromaticity Revisited

Johansson¹,

Jusélius

2005

LOC

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“…While pyrrole is planar and can be referred to as an aromatic system, heavier Group 15 analogues of pyrrole are pyramidal and are therefore non-aromatic. [24] The most prominent structural features are summarized in Table 1 , [18] which indicates partial double-bond character for all of the NÀN bonds, with the N2ÀN3 bond being close to having a bond order of two. Although 4 seems to be predisposed to the release of molecular nitrogen, no fast decomposition was observed.…”

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confidence: 99%

An Unusual Isomerization to Tetraazastiboles

2011

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Dedicated to Professor Peter Klüfers on the occasion of his 60th birthdayPentazoles are aromatic molecules consisting of a fivemembered nitrogen-atom ring (Scheme 1), one of which is bonded to a hydrogen atom (HN 5 ) or an organic substituent (RN 5 ; R is usually an aryl group). They form a class of highly endothermic and explosive compounds. The existence of an all-nitrogen aromatic azole ring, RN 5 (R = C 6 H 5 ), was considered by Clusius and Hurzeler [1] and shown by Huisgen and Ugi [2] in the reaction of phenyldiazonium chloride, [C 6 Substitution of one nitrogen atom in pentazoles by a heavier element of Group 15 leads to isovalent tetraazapnictoles (Scheme 1), RN 4 E (E = P, As, Sb, Bi), which also have electronic structures that are related to those of aromatic hydrocarbons with (4n + 2)p electrons.[3] Only recently, two examples of tetraazapnictoles (E = P, R = Mes* = 2,4,6-tritert-butylphenyl or m-Ter = 2,6-bis(2,4,6-trimethylphenyl)-phenyl;[4a, 5] E = As, [6] R = Mes*) have been isolated and fully characterized. Two different synthetic routes to tetraazapnictoles have been described: [4,6]

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Trends in Inversion Barriers IV. The Group 15 Analogous of Pyrrole

Cited by 47 publications

References 38 publications

The Continuing Development of the Chemistry of Phospholes

The Continuing Development of the Chemistry of Phospholes

Arsole Aromaticity Revisited

An Unusual Isomerization to Tetraazastiboles

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