The hexadehydro-Diels–Alder reaction

Hoye, Thomas R.; Baire, Beeraiah; Niu, Dawen; Willoughby, Patrick H.; Woods, Brian P.

doi:10.1038/nature11518

Cited by 376 publications

(231 citation statements)

References 25 publications

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“…The expected alcohol nucleophilic addition to aryne (Scheme 1, right) was found to be second-order with respect to the alcohol (Figure 1), and consequently is favored only at high concentration of the latter. This computational result is consistent with early success where alcohols were used as solvents, and is also consistent with Hoye's and Lee's earlier results where large excess of alcohols was typically used [11][12]. Interestingly, this mechanistic rationale is in good agreement with a half-century-old finding from Bunnett that alcohol addition to arynes comes with accumulation of negative charge on aryne[4].…”

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confidence: 90%

“…Meanwhile, it also sparked another curiosity standing equally elusive, that is, whether the lack of reactivity of aliphatic carboxylic acids and primary carboxyamides with arynes [7] could be explained by the same model. In fact, if one compares Hoye's and Lee's results [11,12] where acetic acid underwent nucleophilic addition to arynes with Larock's conditions [7] where no synthetically meaningful yield was obtained, it follows that the former success can be, at least partially, attributed to the excess and higher concentration of AcOH [15] which in turn might suggest higher-order kinetics with respect to the acid. It remains questionable as to why phenols behave differently from aliphatic alcohols in the nucleophilic addition with arynes, and why aromatic carboxylic acids behave differently from aliphatic ones [7].…”

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confidence: 99%

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Transfer Hydrogenation vs Nucleophilic Addition: Aryne Reaction with Alcohols

Dubrovskiy¹

2017

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CommentaryMOJ Biorg Org Chem 2017, 1(1): 00004 manner [7]. As an illustrative example, when carbodiimide, a not well recognized nucleophile, and methanol are both present, aryne would selectively react with the former [8]. This seemingly counterintuitive "inertness" of benzyne toward aliphatic alcohols, along with some others highlighted in our recent review [9], constitutes a long-standing curiosity for aryne chemists, both synthetically and mechanistically.

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confidence: 99%

Transfer Hydrogenation vs Nucleophilic Addition: Aryne Reaction with Alcohols

Dubrovskiy¹

2017

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“…The case of an unusually reactive benzyne derivative was reported recently. [3] The aryne was formed in an intramolecular [2þ4] cycloaddition reaction of a triyne and estimated to be exothermic by ,50 kcal mol À1 (1 kcal mol À1 ¼ 4.186 kJ mol À1 ), and it is suggested that this excess energy is the reason for the increased reactivity. [4] contradictory and inconclusive results.…”

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confidence: 99%

“…[12][13][14] Temperatures above 10008C are required to decompose the unactivated methylenimine to HCN under these conditions. [21] CH 3 …”

Section: Introductionmentioning

confidence: 99%

Chemical Activation in Azide and Nitrene Chemistry: Methyl Azide, Phenyl Azide, Naphthyl Azides, Pyridyl Azides, Benzotriazoles, and Triazolopyridines

Wentrup¹

2013

Aust. J. Chem.

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Chemical activation (the formation of 'hot' molecules due to chemical reactions) is ubiquitous in flash vacuum thermolysis (FVT) reactions, and awareness of this phenomenon is indispensable when designing synthetically useful gas-phase reactions. Chemical activation is particularly prevalent in azide chemistry because the interesting singlet nitrenes are high-energy intermediates, and their reactions are highly exothermic. Consequently, chemical activation is observed in the isomerization of methylnitrene CH 3 N to methylenimine (methanimine) CH 2 ¼NH, facilitating the elimination of hydrogen to form HCN or HNC. Rearrangements of phenylnitrene, 1-and 2-naphthylnitrenes, and 2-, 3-and 4-pyridylnitrenes afford cyanocyclopentadiene, 3-and 2-cyanoindenes, and 2-and 3-cyanopyrroles, all showing the effects of chemical activation by undergoing facile interconversion of isomers. Chemical activation can often be reduced or removed entirely by increasing the pressure, thereby promoting collisional deactivation. Larger molecules having more degrees of freedom are better able to dissipate excess energy; therefore the effects of chemical activation are less pronounced or completely absent in the formation of 3-cyanoindole and 1-cyanobenzimidazoles from 3-and 4-quinolylnitrenes and 4-quinazolinylnitrenes, respectively. In compounds possessing nitro groups, chemical activation can cause the loss of the nitro group at nominal temperatures far below those normally needed to cleave the C-NO 2 bond.

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“…In a different direction for substituted benzene synthesis, the benzene core is newly formed. Representative methods include transition metal-catalyzed [2 þ 2 þ 2] or [4 þ 2] reactions such as acetylene trimerizations developed by Reppe et al [9][10][11] In this cycloaddition approach, partial or complete intramolecular reaction is usually indispensable to ensure the regio-selectivity.…”

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confidence: 99%