Origin of a Kinetically Selective Route for Thermoreversible Valence Tautomerism-Based Photoswitching in <i>O</i>‑Heterocycles Containing Conjugated Dienes

Origin of a Kinetically Selective Route for Thermoreversible Valence Tautomerism-Based Photoswitching in <i>O</i>‑Heterocycles Containing Conjugated Dienes

The thermal electrocyclic ring opening of fused <i>cis</i>-cyclobutene to <i>cis</i>,<i>cis</i>-diene is prohibited according to the Woodward–Hoffmann (WH) rules; nonetheless, experiments provide firm evidence for their formation. However, the mechanism, electroni...

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Bibliographic Details
Main Author: Akanksha Ashok Sangolkar (19865681) (author)
Other Authors: Anup Shahi (19865684) (author), Rama Krishna Kadiyam (18445612) (author), Ravinder Pawar (9629292) (author)
Published: 2024
Subjects:
Biophysics
Biochemistry
Genetics
Biotechnology
Cancer
Infectious Diseases
Plant Biology
Computational Biology
Chemical Sciences not elsewhere classified
Physical Sciences not elsewhere classified
woodward – hoffmann
thermoreversible valence tautomerism
thermal ring opening
promotes c –
outperform energy storage
direct disrotatory pathway
conrotatory ring opening
kinetically selective route
>- heterocycles containing
kinetically refutes
kinetically preferred
>- dienes
>- diene
>- cyclobutene
ultimately leads
singlet biradicaloid
results emphasize
rational design
prohibited according
membered cyclic
increased electrophilicity
gain insights
expected h
electronic structure
critical insight
core skeleton
conjugated diene
bond rotation
based photoswitching
available h
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Summary:The thermal electrocyclic ring opening of fused <i>cis</i>-cyclobutene to <i>cis</i>,<i>cis</i>-diene is prohibited according to the Woodward–Hoffmann (WH) rules; nonetheless, experiments provide firm evidence for their formation. However, the mechanism, electronic structure, and behavior during the reaction are ambiguous. Herein, we attempt to gain insights into the mechanism of thermal ring opening in four <i>O</i>-heterocycles containing a conjugated diene as the core skeleton. The results emphasize that the reaction initiates with a conrotatory ring opening to produce a <i>cis</i>,<i>trans</i>-diene as a strained transient intermediate following the WH rules but ultimately leads to a forbidden product. The conversion of <i>cis</i>,<i>trans</i>-diene to <i>cis</i>,<i>cis</i>-diene is kinetically preferred through double-bond rotation, involving the formation of a singlet biradicaloid. The expected H-shift is unfavorable because the requirement of suprafacial H transfer incorporates additional strain, while the transfer of other available H is symmetry-forbidden. The increased electrophilicity at O promotes C–O dissociation in the 8-membered cyclic <i>cis</i>,<i>trans</i>-dienes with fused benzene. This enables thermoreversible photoswitching via a two-step mechanism and kinetically refutes the direct disrotatory pathway. These systems can outperform energy storage, and critical insight into their mechanism with the aid of comprehensive electronic structure analysis would assist in their rational design in the future.

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