Effect of Ring Size and Migratory Groups on [1,<i>n</i>] Suprafacial Shift Reactions. Confirmation of Aromatic and Antiaromatic Transition-State Character by Ring-Current Analysis

Clarke, Joseph; Fowler, Patrick W.; Gronert, Scott; Keeffe, James R.

doi:10.1021/acs.joc.6b01261

Cited by 17 publications

(17 citation statements)

References 52 publications

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“…Further, the [1,5]-shifts in cyclic alkenes like cyclopentadiene, cyclopropene, and cycloheptatriene have also been experimentally and theoretically explored. [21][22][23][24] Not only hydrogen but also halogens are good migrating groups and are known to undergo [1,5]-sigmatropic shifts. 7b, 10,19,[25][26][27][28][29][30][31] To the best of our knowledge, there are no reports that compare the rate of migratory aptitude and stereochemical preference (supra/antara) of halogens during [1,5]-shift in 1,3-pentadiene.…”

Section: Introductionmentioning

confidence: 99%

“…The [1,5]‐hydrogen shift in 1,3‐pentadiene is found to occur via concerted suprafacial fashion. Further, the [1,5]‐shifts in cyclic alkenes like cyclopentadiene, cyclopropene, and cycloheptatriene have also been experimentally and theoretically explored . Not only hydrogen but also halogens are good migrating groups and are known to undergo [1,5]‐sigmatropic shifts 7b, 10, 19, 25–31.…”

Section: Introductionmentioning

confidence: 99%

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Can aromaticity trigger thermal [1,5]‐halogen shift towards the forbidden antarafacial mode?: A density functional case study

Kalpana¹,

Akilandeswari²

2019

J of Physical Organic Chem

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[1,5]‐H shift of (Z,Z) 1,3‐pentadienes are known to take suprafacial mode. The stereochemical fate of the reaction when halogens are involved in the [1,5]‐shift in similar (Z,Z) 1,3‐pentadienes is presented in this work. Interesting tendency of fluorine to take up the forbidden and relatively expensive antarafacial path as an economical route for [1,5]‐fluorine shift is owed to the aromaticity of the transition state. Remarkable correlations between various aromaticity indices (bond alternation coefficient [BAC], harmonic oscillator model of aromaticity [HOMA], nucleus independent chemical shift (NICS), and ellipticity [ξ]) with activation barriers pave solid foundation to the fact that aromaticity of transition states (TS) in pericyclic reaction can manoeuvre the stereochemical course of a reaction. The differential effect of fluorine to other halogens is exemplified by the antara migration while the other halogens (Cl and Br) prefer supra mode. NBO studies and the topological parameter, ellipticity used as a measure of aromatic criterion support the above fact.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Can aromaticity trigger thermal [1,5]‐halogen shift towards the forbidden antarafacial mode?: A density functional case study

Kalpana¹,

Akilandeswari²

2019

J of Physical Organic Chem

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“…[11] Note that these studies focused on the geminally disubstituted compounds, although for monosubstituted cyclopentadienes, the relative stability, suprafacial shift reactions, and intrinsic acidity have been investigated. [12] However, the influence of substituents on hyperconjugative aromaticity in monosubstituted compounds remains uncertain. In addition, when one electronegative and one electropositive substituent are simultaneously considered, which one will dominate?…”

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confidence: 99%

Probing Hyperconjugative Aromaticity of Monosubstituted Cyclopentadienes

et al. 2018

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Hyperconjugation and aromaticity are two of the most important concepts in chemistry. Mulliken and coworkers combined both terms to explain the stability of cyclopentadiene. Here, we carried out DFT calculations on a series of mono-and disubstituted cyclopentadiene derivatives to investigate their hyperconjugative aromaticity. Our results revealed that one electropositive substituent can induce aromaticity, whereas one electronegative substituent prompts nonaromaticity rather than antiaromaticity. When an electronegative substituent and a transition metal as an electropositive substituent were considered simultaneously, a slightly aromatic cyclopentadiene ring could be achieved, whereas an electropositive substituent of the main group in combination with an electronegative one will produce a nonaromatic cyclopentadiene ring.

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“…[9] Recently,F owler and co-workerss howed that electropositive migratory groups( e.g., CH 3 and SiMe 3 )c ould reduce the [1,5]-shift activation energies, whereas the electronegative migratory groups (e.g.,F )l ed to larger activation energies as ar esult of the aromatic and antiaromatic character of the TSs. [10] Owing to many fascinating and ever-increasing manifestations, hyperconjugative aromaticity [11] and [1,5]-shifts [12] in cyclopentadienes have received much attention.I n2 016, the first hyperconjugative aromatic heterocycles containing transition-metal substituents werer eportede xperimentally and computationally. [13] Recently,w e also predicted the most aromatic pyrrolium and cyclopentadiene rings through hyperconjugation [14] caused by transitionmetal substituents.…”

Section: Introductionmentioning

confidence: 99%

“…In 2010, Yáñez and co‐workers proposed that the activation barriers of the [1,5]‐shift could be regulated by migratory groups (e.g., CH 3 , SiH 3 , and GeH 3 ), owing to hyperconjugative aromaticity . Recently, Fowler and co‐workers showed that electropositive migratory groups (e.g., CH 3 and SiMe 3 ) could reduce the [1,5]‐shift activation energies, whereas the electronegative migratory groups (e.g., F) led to larger activation energies as a result of the aromatic and antiaromatic character of the TSs . Owing to many fascinating and ever‐increasing manifestations, hyperconjugative aromaticity and [1,5]‐shifts in cyclopentadienes have received much attention.…”

Section: Introductionmentioning

confidence: 99%

Probing Reaction Mechanism of [1,5]‐Migration in Pyrrolium and Pyrrole Derivatives: Activation of a Stronger Bond in Electropositive Groups Becomes Easier

Xie

Zhao

Chen

et al. 2019

Chemistry An Asian Journal

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The [1,5]-migration reaction has attractedc onsiderable attention from experimentalists andt heoreticians for decades. Although it has been extensively investigated in various systems, studies on pyrrolium derivatives are underdeveloped. Herein, at heoretical study on the reaction mechanism of [1,5]-migrationi nb oth pyrroliuma nd pyrrole derivatives is presented. The results reveal lower activation barriers in [1,5]-migration of electropositive groups (AuPMe 3 and SnH 3 )i np yrrolium derivatives, although the bond dissociation energies of the AuÀNb ond (98.8 kcal mol À1 )a nd SnÀN bond (81.7 kcal mol À1 )a re larger than that of the NÀFb ond (57.6 kcal mol À1 ). The unexpectedly lower activation barriers (4.5 and 4.9 kcal mol À1 for AuPMe 3 and SnH 3 ,r espectively) for [1,5]-migration of electropositive groups,i nc omparison with the [1,5]-fluorine shift, can be attributed to aromaticity stabilizing the transition states, as revealed by significantly negative nucleus-independent chemical shift (NICS) values. Further studies indicate that charge distribution and frontier molecular orbitals also plays ome roles in [1,5]-migration of pyrrolium derivatives.[a] Q.

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Effect of Ring Size and Migratory Groups on [1,n] Suprafacial Shift Reactions. Confirmation of Aromatic and Antiaromatic Transition-State Character by Ring-Current Analysis

Cited by 17 publications

References 52 publications

Can aromaticity trigger thermal [1,5]‐halogen shift towards the forbidden antarafacial mode?: A density functional case study

Can aromaticity trigger thermal [1,5]‐halogen shift towards the forbidden antarafacial mode?: A density functional case study

Probing Hyperconjugative Aromaticity of Monosubstituted Cyclopentadienes

Probing Reaction Mechanism of [1,5]‐Migration in Pyrrolium and Pyrrole Derivatives: Activation of a Stronger Bond in Electropositive Groups Becomes Easier

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