Radical 1,2‐O→C Transposition for Conversion of Phenols into Benzoates by O‐Neophyl Rearrangement/Fragmentation Cascade

Baroudi, Abdulkader; Alicea, Jeremiah; Alabugin, Igor V.

doi:10.1002/chem.201001056

Cited by 26 publications

(13 citation statements)

References 46 publications

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“…The first calculated energy profile for this process presented in Figure 2 illustrates that this reaction should be significantly slower than the O-and N-neophyl rearrangement in this system. Similar to the previous DFT calculations performed on the rearrangement of diaryl thiocarbonates, [3] our computational analysis at the UB3LYP/6-31 + G** level on thiocarbamates suggests a concerted mechanism for the O-neophyl rearrangement/fragmentation pathway. This observation contrasts with earlier computational [2,12] and experimental [13] support for a stepwise mechanism with the formation of a three-membered radical intermediate in systems where the O-neophyl rearrangement step is not coupled with fragmentation.…”

supporting

confidence: 84%

“…(1)]), [2] our lab has re-cently developed a convenient procedure for the conversion of phenols into benzoate esters. [3] This transformation was designed through rerouting the reaction via an O-neophyl rearrangement [5] /fragmentation sequence (Scheme 1,A C H T U N G T R E N N U N G [Eq. (2)]).…”

mentioning

confidence: 99%

“…The rearrangement of O-alkyl-substituted thiocarbonates leads to the well-known radical fragmentation (incorporated in the Barton-McCombie deoxygenation pathway) without the formation of rearrangement product (benzoate ester). [3] In contrast, radical fragmentation of C À N bonds through the same process is inefficient. For example, although reversible radical abstraction of the a-hydrogen readily occurs in amines, no scission of C À N bonds is observed under these conditions.…”

mentioning

confidence: 99%

“…[a] Unless otherwise specified, all reactions were carried out at 11 mm of thiocarbamate, with the 1:2 molar ratio of radical initiator to Et 3 radical-stabilizing effect of the substituents. For example, thiocarbamates with para-OMe or -CN substituents do not show higher reaction yields.…”

mentioning

confidence: 99%

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Metal‐Free Transformation of Phenols into Substituted Benzamides: A Highly Selective Radical 1,2‐O→C Transposition in O‐Aryl‐N‐phenylthiocarbamates

Baroudi

Flack

Alabugin

2010

Chemistry A European J

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Radical merry‐go‐round: A highly efficient metal‐free transformation of phenols into benzamides is designed through one‐step conversion of phenols to aryl thiocarbamates and a subsequent radical addition/rearrangement/fragmentation cascade. Computational analysis fully rationalizes the experimentally observed selectivity. Despite the possible competition from NC fragmentation and N‐neophyl rearrangement, the transformation exclusively follows the most kinetically and thermodynamically favored O‐neophyl rearrangement path.

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confidence: 84%

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Metal‐Free Transformation of Phenols into Substituted Benzamides: A Highly Selective Radical 1,2‐O→C Transposition in O‐Aryl‐N‐phenylthiocarbamates

Baroudi

Flack

Alabugin

2010

Chemistry A European J

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“… Selected examples of radical fragmentations in synthesis. Left: Scission of a weak CS is used to shift the equilibrium for an unfavorable rearrangement 10b–d. Center: Rare example of β‐scission of a CC bond, reported by Zard et al 10f.…”

Section: Resultsmentioning

confidence: 99%

Design of Leaving Groups in Radical CC Fragmentations: Through‐Bond 2c–3e Interactions in Self‐Terminating Radical Cascades

Mondal

Gold

Mohamed

et al. 2014

Chemistry A European J

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Radical cascades terminated by β-scission of exocyclic CC bonds allow for the formation of aromatic products. Whereas β-scission is common for weaker bonds, achieving this reactivity for carbon-carbon bonds requires careful design of radical leaving groups. It has now been found that the energetic penalty for breaking a strong σ-bond can be compensated by the gain of aromaticity in the product and by the stabilizing two-center, three-electron "half-bond" present in the radical fragment. Furthermore, through-bond communication of a radical and a lone pair accelerates the fragmentation by selectively stabilizing the transition state. The stereoelectronic design of radical leaving groups leads to a new, convenient route to Sn-functionalized aromatics.

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Hydrosilanes

Ho¹,

Fieser²,

Fieser³

2013

Fieser and Fieser's Reagents for Organic Synthesis

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Radical 1,2‐O→C Transposition for Conversion of Phenols into Benzoates by O‐Neophyl Rearrangement/Fragmentation Cascade

Cited by 26 publications

References 46 publications

Metal‐Free Transformation of Phenols into Substituted Benzamides: A Highly Selective Radical 1,2‐O→C Transposition in O‐Aryl‐N‐phenylthiocarbamates

Metal‐Free Transformation of Phenols into Substituted Benzamides: A Highly Selective Radical 1,2‐O→C Transposition in O‐Aryl‐N‐phenylthiocarbamates

Design of Leaving Groups in Radical CC Fragmentations: Through‐Bond 2c–3e Interactions in Self‐Terminating Radical Cascades

Hydrosilanes

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