Previtamin D:Z–Ephotoisomerizationviaa Hula-twist conical intersection

Fuß, Werner

doi:10.1039/c9cp00500e

Cited by 8 publications

(6 citation statements)

References 65 publications

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“…The hula-twist mechanism for double bond photoisomerization provides another example where the cooperative motion of multiple modes (concerted single-bond and double bond rotation) drives photochemical reactions and has been observed in vitamin D, polyenes and stilbene, all involving a type 1 CoIn. 107,[208][209][210] Given the type of molecular skeleton of the chromophore and the protein constraints a hula-twist mechanism (aborted or not aborted) may also operate in phytochromes. Additionally, such a mechanism has been discussed in the family of green fluorescent proteins (GFPs), 211 which act as a live-cell fluorescent imaging tool to monitor cellular processes, 40 although involving an electronically distinct S 1 (pp*)/S 0 CoIn due to the CT nature of the ES (i.e.…”

Section: Other Ultrafast Double Bond Photoisomerizationsmentioning

confidence: 99%

From a one-mode to a multi-mode understanding of conical intersection mediated ultrafast organic photochemical reactions

Boeije

Olivucci

2023

Chem. Soc. Rev.

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Section: Other Ultrafast Double Bond Photoisomerizationsmentioning

confidence: 99%

From a one-mode to a multi-mode understanding of conical intersection mediated ultrafast organic photochemical reactions

Boeije

Olivucci

2023

Chem. Soc. Rev.

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“…What can we learn about chemical reactivity by focusing on W–H forbidden reactions rather than W–H allowed reactions? Photochemical electrocyclizations involve more complicated potential energy surfaces − and are not discussed in detail here. We also explored the meaning of "violations" of the W-H rules.…”

Section: Introductionmentioning

confidence: 99%

A 21st Century View of Allowed and Forbidden Electrocyclic Reactions

Zhou,

Kukier,

Gordiy

et al. 2023

J. Org. Chem.

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In 1965, Woodward and Hoffmann proposed a theory to predict the stereochemistry of electrocyclic reactions, which, after expansion and generalization, became known as the Woodward−Hoffmann Rules. Subsequently, Longuet-Higgins and Abrahamson used correlation diagrams to propose that the stereoselectivity of electrocyclizations could be explained by the correlation of reactant and product orbitals with the same symmetry. Immediately thereafter, Hoffmann and Woodward applied correlation diagrams to explain the mechanism of cycloadditions. We describe these discoveries and their evolution. We now report an investigation of various electrocyclic reactions using DFT and CASSCF. We track the frontier molecular orbitals along the intrinsic reaction coordinate and modeled trajectories and examine the correlation between HOMO and LUMO for thermally forbidden systems. We also investigate the electrocyclizations of several highly polarized systems for which the Houk group had predicted that donor−acceptor substitution can induce zwitterionic character, thereby providing low-energy pathways for formally forbidden reactions. We conclude with perspectives on the field of pericyclic reactions, including a refinement as the meaning of Woodward and Hoffmann's "Violations. There are none!" Lastly, we comment on the burgeoning influence of computations on all fields of chemistry.

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“…Furthermore, the study of these mechanisms is notoriously difficult because thermal isomerization about carbon–carbon single bonds can mix photoproducts. As a result, many questions and debate − surround the interpretation of photoisomerization mechanisms, and this confusion inhibits rational design.…”

Section: Introductionmentioning

confidence: 99%

The Mechanics of the Bicycle Pedal Photoisomerization in Crystalline cis,cis-1,4-Diphenyl-1,3-butadiene

2020

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Direct irradiation of crystalline cis,cis-1,4-diphenyl-1,3-butadiene (cc-DPB) forms trans,trans-1,4-diphenyl-1,3,-butadiene via a concerted two bond isomerization called the bicycle pedal mechanism. However, little is known about photoisomerization pathways in the solid-state and there has been much debate surrounding the interpretation of volume-conserving isomerization mechanisms. The bicycle pedal photoisomerization is investigated using the QM/MM complete active space self-consistent field (CASSCF)/Amber force-field method. Important details about how the steric environment influences isomerization mechanisms are revealed including how the one-bond flip and hula-twist mechanisms are suppressed by the crystal cavity, the nature of the seam space in steric environments, and the features of the bicycle pedal mechanism. Specifically, in the bicycle pedal the phenyl rings of cc-DPB are locked in place and the intermolecular packing allows passageway for rotation of the central diene in a volume-conserving manner. In contrast, the bicycle pedal rotation in the gas-phase is not a stable pathway, so single-bond rotation mechanisms become operative instead. The present models, however, do not capture the quantitative activation barriers and more work is needed to better model reactions in crystals. Lastly, the reaction barriers of the different crystalline conformations within the unit cell of cc-DPB are compared to investigate the possibility for conformation-dependent isomerization. Although some difference in reaction barriers are observed, the difference is most likely not responsible for the experimentally observed periods of fast and slow conversion.

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Previtamin D:Z–Ephotoisomerizationviaa Hula-twist conical intersection

Cited by 8 publications

References 65 publications

From a one-mode to a multi-mode understanding of conical intersection mediated ultrafast organic photochemical reactions

From a one-mode to a multi-mode understanding of conical intersection mediated ultrafast organic photochemical reactions

A 21st Century View of Allowed and Forbidden Electrocyclic Reactions

The Mechanics of the Bicycle Pedal Photoisomerization in Crystalline cis,cis-1,4-Diphenyl-1,3-butadiene

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