Rearrangement and Hydrogen Scrambling Pathways of the Toluene Radical Cation: A Computational Study

Norberg, Daniel; Larsson, Per-Erik; Salhi-Benachenhou, Nessima

doi:10.1021/jp711166d

Cited by 12 publications

(11 citation statements)

References 20 publications

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“…The bond angles also exhibit a proportionate deviation to facilitate the 1,4‐migration 23. Such large geometric distortions in hydrogen migrations have also been reported with different substrates 24…”

Section: Resultssupporting

confidence: 64%

“…[23] Such large geometric distortions in hydrogen migrations have also been reported with different substrates. [24] The comparison between the proton transfer and hydride transfer involved in L a to M a and M a to Y conversions, respectively, reveals that the proton migratory pathways generally prefer a series of 1,2-migrations, whereas several 1,2migrations in the case of hydride transfer involve relatively higher energy transition states. In the case of zwitterionic intermediate M a only the first 1,2-hydride transfer is found to be favorable.…”

Section: Resultsmentioning

confidence: 99%

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On the Origin of Reversible Hydrogen Activation by Phosphine–Boranes

Ramanan

Sunoj

2009

Chemistry A European J

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Mechanistic insights into the factors responsible for the reversible hydrogen-activation ability exhibited by an aryl phosphine-borane system ((CH(3))(2)P-C(6)F(4)-B(CF(3))(2)) are presented. A detailed evaluation of the energies of various intermediates, generated by the addition of molecular hydrogen, and their interconverting barriers have been carried out using ab initio and DFT methods. Several rearrangement possibilities of the H(2)-phosphino-borane adduct have been investigated so as to unravel the lower energy pathways that convert the initial adduct to a series of other intermediates. The initial adduct formed by the heterolytic addition of a molecular hydrogen across the C-B bond is identified to undergo a series of rearrangement reactions until it terminates at the C-P end of the molecule. Among the possible 1,n-migrations (for which n=1-5), 1,2-proton migrations are found to possess lower energy transition states, whereas 1,2-hydride (in a zwitterionic intermediate) and 1,4-proton-coupled electron transfers exhibited much higher energy transition states. The minimum energy pathway for the transfer of a proton and hydride from the C-B bond to the C-P bond is found to involve a cascade of 1,2-proton transfers followed by a 1,2-hydride migration and finally a 1,4-proton-coupled electron transfer. The higher energy pathways identified for the hydride transfer suggest the possibility of a cascade of reversible proton migrations from a thermodynamically stable intermediate (M(a)). Possible uptake of two hydrogen molecules by the phosphine-borane system is additionally considered in the present study, in which relatively higher barriers than those with one molecule of hydrogen are observed. The computed thermodynamic parameters are found to be in accordance with the experimental observations, in which the uptake and storage of molecular hydrogen are carried out at lower temperatures whereas the liberation demands elevated temperatures.

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Section: Resultssupporting

confidence: 64%

Section: Resultsmentioning

confidence: 99%

On the Origin of Reversible Hydrogen Activation by Phosphine–Boranes

Ramanan

Sunoj

2009

Chemistry A European J

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“…The [1,3]‐ and [1,4]‐methyl shifts require very high activation energies. Thus, it is logical to conclude that the O ‐ and N ‐alkyl pterins, for example, 3 and 4 , are non‐interconverting species, unlike walk processes observed for molecular rearrangements , such as the walk rearrangement of bicyclo[2.1.0]pent‐2‐ene .…”

Section: Resultsmentioning

confidence: 99%

“…The [1,3]-and [1,4]-methyl shifts require very high activation energies. Thus, it is logical to conclude that the O-and N-alkyl pterins, for example, 3 and 4, are non-interconverting species, unlike walk processes observed for molecular rearrangements (33)(34)(35)(36)(37)(38)(39)(40)(41)(42)(43), such as the walk rearrangement of bicyclo[2.1.0]pent-2ene (44). Table 5 lists the computed log P and log D values that were obtained with the ChemAxon algorithm.…”

Section: Dft Computed Stabilities Of Alkyl Pterin Regioisomersmentioning

confidence: 99%

Kinetic Control in the Regioselective Alkylation of Pterin Sensitizers: A Synthetic, Photochemical, and Theoretical Study

Walalawela

Vignoni

Urrutia

et al. 2018

Photochem & Photobiology

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Alkylation patterns and excited-state properties of pterins were examined both experimentally and theoretically. 2D NMR spectroscopy was used to characterize the pterin derivatives, revealing undoubtedly that the decyl chains were coupled to either the O4 or N3 sites on the pterin. At a temperature of 70°C, the pterin alkylation regioselectively favored the O4 over the N3. The O4 was also favored when using solvents, in which the reactants had increased solubility, namely N,N-dimethylformamide and N,N-dimethylacetamide, rather than solvents in which the reactants had very low solubility (tetrahydrofuran and dichloromethane). Density functional theory (DFT) computed enthalpies correlate to regioselectivity being kinetically driven because the less stable O-isomer forms in higher yield than the more stable N-isomer. Once formed these compounds did not interconvert thermally or undergo a unimolecular "walk" rearrangement. Mechanistic rationale for the factors underlying the regioselective alkylation of pterins is suggested, where kinetic rather than thermodynamic factors are key in the higher yield of the O-isomer. Computations also predicted greater solubility and reduced triplet state energetics thereby improving the properties of the alkylated pterins as O sensitizers. Insight on thermal and photostability of the alkylated pterins is also provided.

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“…The one directly connecting 1 + and 3 + , originally proposed by Dewar and Landman, 8 consists of a [1,3]-H shift, whereby the methyl hydrogen migrates to the ortho-position to form 3 + , followed by an intramolecular cyclization to form the transient distonic radical cation 6 + , which readily undergoes ring expansion to produce 5 + . However, quantum chemical calculations 22 have shown that it is more favorable to first form 2 + and then 3 + than to directly convert 1 + to 3 + . According to ab initio calculations the Hoffman mechanism is energetically slightly preferred over the Dewar−Landman mechanism.…”

Section: Introductionmentioning

confidence: 99%

Unveiling New Isomers and Rearrangement Routes on the C₇H₈⁺ Potential Energy Surface

2019

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The unimolecular reactions of C7H8 + radical cations are among those most studied by mass spectrometry, especially the rearrangement of toluene and cycloheptatriene molecular ions, which are directly connected to the formation of benzylium and tropylium cations. This study reveals important new isomers and isomerization pathways on the C7H8 + potential energy surface, through the application of gas-phase electronic photodissociation spectroscopy in conjunction with ab initio calculations. Presented are the first gas-phase vibrationally resolved electronic spectra of the o-isotoluene, norcaradiene, bicyclo[3.2.0]hepta-2,6-diene radical cations, and ring-opened products from cyclic C7H8 + species. The isomerization route from the norbornadiene radical cation to the toluene radical cation, which competes with isomerization to the bicyclo[2.2.1]hepta-2-ene-5-yl-7-ylium radical cation, is identified. Further, this work expands understanding of the C7H8 + potential energy surface by connecting spiro[2.4]hepta-4,6-diene and acyclic 1,2,4,6-heptatetraene radical cations, and confirms the important role of the o-isotoluene radical cation in the interconversion pathways of C7H8 + species.

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Rearrangement and Hydrogen Scrambling Pathways of the Toluene Radical Cation: A Computational Study

Cited by 12 publications

References 20 publications

On the Origin of Reversible Hydrogen Activation by Phosphine–Boranes

On the Origin of Reversible Hydrogen Activation by Phosphine–Boranes

Kinetic Control in the Regioselective Alkylation of Pterin Sensitizers: A Synthetic, Photochemical, and Theoretical Study

Unveiling New Isomers and Rearrangement Routes on the C₇H₈⁺ Potential Energy Surface

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Rearrangement and Hydrogen Scrambling Pathways of the Toluene Radical Cation: A Computational Study

Cited by 12 publications

References 20 publications

On the Origin of Reversible Hydrogen Activation by Phosphine–Boranes

On the Origin of Reversible Hydrogen Activation by Phosphine–Boranes

Kinetic Control in the Regioselective Alkylation of Pterin Sensitizers: A Synthetic, Photochemical, and Theoretical Study

Unveiling New Isomers and Rearrangement Routes on the C7H8+ Potential Energy Surface

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Product

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About

Unveiling New Isomers and Rearrangement Routes on the C₇H₈⁺ Potential Energy Surface