Direct Observation of the Reduction of Aryl Halides by a Photoexcited Perylene Diimide Radical Anion

Zeman, Charles J.; Kim, Soojin; Zhang, Fang; Schanze, Kirk S.

doi:10.1021/jacs.9b13027

Cited by 114 publications

(129 citation statements)

References 25 publications

(42 reference statements)

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“…A very recent picosecond‐transient‐absorption study provides direct evidence for the bimolecular electron transfer between photoexcited PDI .− and a range of substrates with reduction potentials more positive than −1.7 V vs. SCE . However, for substrates with more negative potentials (and this is likely the case for several of the initially investigated aryl chlorides), a different mechanism, possibly a thermally activated pathway, seems to be operative …”

Section: The Next Level: Reductive Excited‐state Quenching Followed Bmentioning

confidence: 99%

Multi‐Photon Excitation in Photoredox Catalysis: Concepts, Applications, Methods

2020

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The energy of visible photons and the accessible redox potentials of common photocatalysts set thermodynamic limits to photochemical reactions that can be driven by traditional visible‐light irradiation. UV excitation can be damaging and induce side reactions, hence visible or even near‐IR light is usually preferable. Thus, photochemistry currently faces two divergent challenges, namely the desire to perform ever more thermodynamically demanding reactions with increasingly lower photon energies. The pooling of two low‐energy photons can address both challenges simultaneously, and whilst multi‐photon spectroscopy is well established, synthetic photoredox chemistry has only recently started to exploit multi‐photon processes on the preparative scale. Herein, we have a critical look at currently developed reactions and mechanistic concepts, discuss pertinent experimental methods, and provide an outlook into possible future developments of this rapidly emerging area.

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Section: The Next Level: Reductive Excited‐state Quenching Followed Bmentioning

confidence: 99%

Multi‐Photon Excitation in Photoredox Catalysis: Concepts, Applications, Methods

2020

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“…Conversely, Zhang, Schanze, and co-workers have recently reported the use of picosecond time-resolved transient absorption spectroscopy to monitor the formation of A * À * and its bimolecular quenching by aryl halides 1 through Stern-Volmer studies. [33] The authors found that A * À * underwent efficient PET with electron-poor halides 1 having reduction potential > À 1.7 V vs SCE. Besides, they calculated the potential for the couple A * À */A as À 1.87 V vs SCE.…”

Section: Mechanistic Discussion: Reduction Of Aryl Halidesmentioning

confidence: 99%

Use of Perylene Diimides in Synthetic Photochemistry

2021

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Dedicated to Professor Franco Cozzi on the occasion of his 70th birthday. Perylene diimides (PDIs) are valuable organic chromophores that stand out for their outstanding optical and redox properties. Owing to these features, PDIs have emerged as prominent dyes capable of acting as photocatalysts for numerous relevant organic transformations. This Minireview highlights the recent advances in the application of PDIs in organic photocatalysis. The various mechanistic pathways of the photo-reduction reaction of aryl halides, recently proposed in independent studies, are discussed with an eye to unsolved challenges and forward-looking opportunities regarding the use of PDIs within this field.

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“…Eine aktuelle Studie zur transienten Pikosekunden‐Absorption lieferte direkte Belege für bimolekulare Elektronentransferreaktionen zwischen angeregtem PDI .− und einer Auswahl an Substraten mit Reduktionspotentialen, die positiver als −1.7 V gegen SCE sind . Für Substrate mit negativeren Potentialen (und das ist wahrscheinlich der Fall für einige der anfänglich untersuchten Arylchloride) scheint hingegen ein anderer Mechanismus abzulaufen, möglicherweise ein thermisch aktivierter Reaktionsweg …”

Section: Die Nächste Ebene: Reduktives Löschen Angeregter Zustände Gunclassified

Multiphotonen‐Anregung in der Photoredoxkatalyse: Konzepte, Anwendungen und Methoden

2020

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Die Energie sichtbarer Photonen und die zugänglichen Redoxpotentiale üblicher Photokatalysatoren schränken die Anzahl derjenigen Photoreaktionen ein, die durch sichtbares Licht angetrieben werden können. Da UV‐Anregung schädlich ist und häufig Nebenreaktionen auslöst, ist sichtbares Licht oder sogar NIR‐Strahlung vorzuziehen. Die Photochemie befasst sich momentan mit einer zweischneidigen Herausforderung, und zwar mit dem Wunsch, immer thermodynamisch anspruchsvollere Reaktionen mit immer kleineren Photonenenergien durchführen zu können. Das Akkumulieren der Energie zweier energiearmer Photonen kann dazu passende Lösungsansätze liefern. Obwohl die Multiphotonen‐Spektroskopie gut etabliert ist, haben Photoredox‐Synthesechemiker erst kürzlich begonnen, Multiphotonen‐Prozesse präparativ zu nutzen. Hier werfen wir einen kritischen Blick auf kürzlich entwickelte Reaktionen und mechanistische Konzepte, diskutieren einschlägige experimentelle Methoden und geben einen Ausblick auf mögliche zukünftige Entwicklungen dieses jungen Forschungsgebiets.

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Direct Observation of the Reduction of Aryl Halides by a Photoexcited Perylene Diimide Radical Anion

Cited by 114 publications

References 25 publications

Multi‐Photon Excitation in Photoredox Catalysis: Concepts, Applications, Methods

Multi‐Photon Excitation in Photoredox Catalysis: Concepts, Applications, Methods

Use of Perylene Diimides in Synthetic Photochemistry

Multiphotonen‐Anregung in der Photoredoxkatalyse: Konzepte, Anwendungen und Methoden

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