Direct structural observation of ultrafast photoisomerization dynamics in sinapate esters

Sinapate esters have been extensively studied for their potential application in ‘nature-inspired’ photoprotection. There is general consensus that the relaxation mechanism of sinapate esters following photoexcitation with ultraviolet radiation is mediated by geometric isomerization. This has been l...

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Veröffentlicht in:Communications chemistry 2022-10, Vol.5 (1), p.141-141, Article 141
Hauptverfasser: Abiola, Temitope T., Toldo, Josene M., do Casal, Mariana T., Flourat, Amandine L., Rioux, Benjamin, Woolley, Jack M., Murdock, Daniel, Allais, Florent, Barbatti, Mario, Stavros, Vasilios G.
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Sprache:eng
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Zusammenfassung:Sinapate esters have been extensively studied for their potential application in ‘nature-inspired’ photoprotection. There is general consensus that the relaxation mechanism of sinapate esters following photoexcitation with ultraviolet radiation is mediated by geometric isomerization. This has been largely inferred through indirect studies involving transient electronic absorption spectroscopy in conjunction with steady-state spectroscopies. However, to-date, there is no direct experimental evidence tracking the formation of the photoisomer in real-time. Using transient vibrational absorption spectroscopy, we report on the direct structural changes that occur upon photoexcitation, resulting in the photoisomer formation. Our mechanistic analysis predicts that, from the photoprepared ππ* state, internal conversion takes place through a conical intersection (CI) near the geometry of the initial isomer. Our calculations suggest that different CI topographies at relevant points on the seam of intersection may influence the isomerization yield. Altogether, we provide compelling evidence suggesting that a sinapate ester’s geometric isomerization can be a more complex dynamical process than originally thought. Photoinduced isomerization reactions can be used to efficiently dissipate absorbed energy in photosystems such as molecular motors, but the ultrafast processes are challenging to characterize. Here, the authors track the formation of the E and Z isomers of ethyl sinapate in real time via transient vibrational absorption spectroscopy and find that photoinduced internal conversion occurs at multiple points along the potential energy surface.
ISSN:2399-3669
2399-3669
DOI:10.1038/s42004-022-00757-6