Forward and Backward Pericyclic Photochemical Reactions Have Intermediates in Common, Yet Cyclobutenes Break the Rules

Fuß, Werner; Schmid, W. E.; Trushin, Sergei A.; Billone, Paul S.; Leigh, William J.

doi:10.1002/cphc.200600639

Cited by 10 publications

(10 citation statements)

References 39 publications

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“…They involve forces connected with the excitation of the p system, for which the s bonds are a minor perturbation at most, whereas the Woodward-Hoffmann (WH) rules are based on forces and interactions that involve both p and s electrons. These rules and forces become active only later, when the distortion is sufficient that a suitable s bond can interact with the p system [34,56,97] (by contrast, one can read often that the motion follows the WH rules from the beginning. But this opinion would also be in conflict with the cases, where both conrotatory and disrotatory alternative reactions are possible, such as in several examples of Section 3.2.…”

Section: Further Path To the Last Conical Intersectionmentioning

confidence: 94%

“…In the case of polyenes, however, the minima and CIs for forward and backward reactions typically do not coincide [21,97], in contrast to pericyclic reactions, where they are in common for the two processes according to theory and experiments [56,112].…”

Section: The Woodward-hoffmann Rules and The Dark Statementioning

confidence: 95%

“…The initial acceleration is always in the direction of the FCactive coordinates, as repeatedly pointed out (e.g., in [33,56,97], in particular in [34]). This is already implied by their definition.…”

Section: Further Path To the Last Conical Intersectionmentioning

confidence: 98%

“…This includes -electrocyclic ring opening of cyclohexadiene and derivatives (even large molecules -although with relatively localized excitation -such as 7-dehydrocholesterol [40,[51][52][53]), as described above; ring closure of dienes to form cyclobutenes [54,55] and the corresponding ring opening [56], ring opening of cyclooctatriene to octatetraene [57], -formation of bicyclo [110]alkanes from dienes [48,55,58]. Also formation of bicyclo[3.1.0]alkenes from trienes must be ultrafast, as it can compete with cis-trans isomerization [28,41,42,48,49,59], -[2 + 2]-cycloaddition to cyclobutanes [60][61][62], including also the dimerization of cyclohexadiene, which at high concentration can compete with the ultrafast ring opening [2] ([2 + 2]-cycloaddition in a divinylcyclophane takes longer -13.5 ps [63] -perhaps due to unfavourable geometry and/or too much delocalization of the excitation), -sigmatropic hydrogen 1,3-and 1,7-migration [55,64-68] and a suggested antarafacial H 1,5-migration (Scheme 4 and context in [69], proposed geometry confirmed in Fig.…”

Section: More Ultrafast Pericyclic Reactions and Cis-trans Isomerizatmentioning

confidence: 98%

“…But this opinion would also be in conflict with the cases, where both conrotatory and disrotatory alternative reactions are possible, such as in several examples of Section 3.2. The initial motion along FC active coordinates was also crucial for explaining the partially anti-WH behavior of photochemical ring opening of cyclobutenes [56]; for some details, see Section 4). When the WH forces are activated, the direction of the slopes change, which also influences the motion of the wave packet.…”

Section: Further Path To the Last Conical Intersectionmentioning

confidence: 99%

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Predistortion amplified in the excited state

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Section: Further Path To the Last Conical Intersectionmentioning

confidence: 94%

Section: The Woodward-hoffmann Rules and The Dark Statementioning

confidence: 95%

Section: Further Path To the Last Conical Intersectionmentioning

confidence: 98%

Section: More Ultrafast Pericyclic Reactions and Cis-trans Isomerizatmentioning

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confidence: 99%

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Hula-twist cis–trans isomerization: The role of internal forces and the origin of regioselectivity

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Ultrafast Excited State Dynamics of Spatially Confined Organic Molecules

2022

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This Feature Article highlights the role of spatial confinement in controlling the fundamental behavior of molecules. Select examples illustrate the value of using space as a tool to control and understand excited-state dynamics through a combination of ultrafast spectroscopy and conventional steadystate methods. Molecules of interest were confined within a closed molecular capsule, derived from a cavitand known as octa acid (OA), whose internal void space is sufficient to accommodate molecules as long as tetracene and as wide as pyrene. The free space, i.e., the space that is left following the occupation of the guest within the host, is shown to play a significant role in altering the behavior of guest molecules in the excited state. The results reported here suggest that in addition to weak interactions that are commonly emphasized in supramolecular chemistry, the extent of empty space (i.e., the remaining void space within the capsule) is important in controlling the excited-state behavior of confined molecules on ultrafast time scales. For example, the role of free space in controlling the excited-state dynamics of guest molecules is highlighted by probing the cis−trans isomerization of stilbenes and azobenzenes within the OA capsule. Isomerization of both types of molecule are slowed when they are confined within a small space, with encapsulated azobenzenes taking a different reaction pathway compared to that in solution upon excitation to S 2 . In addition to steric constraints, confinement of reactive molecules in a small space helps to override the need for diffusion to bring the reactants together, thus enabling the measurement of processes that occur faster than the time scale for diffusion. The advantages of reducing free space and confining reactive molecules are illustrated by recording unprecedented excimer emission from anthracene and by measuring ultrafast electron transfer rates across the organic molecular wall. By monitoring the translational motion of anthracene pairs in a restricted space, it has been possible to document the pathway undertaken by excited anthracene from inception to the formation of the excimer on the excited-state surface. Similarly, ultrafast electron transfer experiments pursued here have established that the process is not hindered by a molecular wall. Apparently, the electron can cross the OA capsule wall provided the donor and acceptor are in close proximity. Measurements on the ultrafast time scale provide crucial insights for each of the examples presented here, emphasizing the value of both "space" and "time" in controlling and understanding the dynamics of excited molecules.

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Forward and Backward Pericyclic Photochemical Reactions Have Intermediates in Common, Yet Cyclobutenes Break the Rules

Cited by 10 publications

References 39 publications

Predistortion amplified in the excited state

Predistortion amplified in the excited state

Hula-twist cis–trans isomerization: The role of internal forces and the origin of regioselectivity

Ultrafast Excited State Dynamics of Spatially Confined Organic Molecules

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