Litcius/Paper detail

Designing High-Triplet-Yield Phenothiazine Donor–Acceptor Complexes for Photoredox Catalysis

Steven M. Sartor, Cameron H. Chrisman, Ryan M. Pearson, Garret M. Miyake, Niels H. Damrauer

2020The Journal of Physical Chemistry A46 citationsDOI

Abstract

Phenothiazine, owing to its ease of oxidation and modularity with respect to facile functionalization, is an attractive central chemical unit from which to construct highly reducing organic photoredox catalysts. While design improvements have been made in the community, the yield of intersystem crossing (ΦISC), which determines access to the long-lived triplet excited state, has yet to be systematically optimized. Herein, we explore the impacts of N-aryl substituent variation on excited-state dynamics using picosecond to millisecond transient absorption and emission spectroscopies. Design principles are uncovered that center on controlling the energy of an intermediate charge transfer (CT) state within the singlet excited-state manifold, which, in turn, dictates the yield of CT-state formation and the rate constants for its depletion. Ultimately, we find ΦISC to be highly sensitive to the electron-withdrawing character of the N-aryl electron acceptor in the aforementioned CT state, with ΦISC ranging from ∼0 to 0.96.

Topics & Concepts

Intersystem crossingPhotochemistryExcited stateUltrafast laser spectroscopyQuantum yieldPhenothiazineChemistryAcceptorTriplet stateSinglet stateSinglet fissionElectron donorYield (engineering)Electron acceptorRational designMaterials scienceCatalysisFluorescenceNanotechnologyAtomic physicsPhysicsOrganic chemistrySpectroscopyMedicinePharmacologyQuantum mechanicsMetallurgyCondensed matter physicsRadical Photochemical ReactionsSulfur-Based Synthesis TechniquesOrganic Light-Emitting Diodes Research