Abstract
Photoinduced energy transfer (PEnT) reactions are a subset of photochemical reactions that involve the indirect photoactivation of substrates following an energy transfer from a photoexcited sensitizer/photocatalyst. Examples of PEnT reactions include E/Z isomerizations, [2+2] cycloadditions and sigmatropic shifts. Here we introduce a family of diindolocarbazole (DICz) multi-resonant thermally activated delayed fluorescent (MR-TADF) photocatalysts (PCs), DiICztBu4, DiICzMes4, DiICztBuCz4 and DiICztBuDPA4, that have relatively high triplet energies (ET). We cross-compare their and relevant literature reference PCs’ photocatalytic behaviour in five distinct PEnT reactions. We demonstrate that the use of the DiCz PCs consistently lead to more rapid reaction rates and higher yields compared to the widely used 4CzIPN. DiICztBu4, DiICzMes4 and DiICztBuCz4 possess similar ET but decreasing singlet-triplet energy gaps, EST, enabling for the first time a comparison of the dependency of both the reaction kinetics and the final yield with this photophysical parameter. While we observed no direct correlation between ∆EST and either the reaction rate or yield, these three PCs are fast and efficient across four Dexter Energy Transfer (DET) reactions and are able to excite substrates with high triplet energies as high as 3.0 eV. We observed that when the reaction kinetics are fast, there is little sensitivity to quenching of the excited PC by oxygen, implying that DET to the substrate is competitive with DET to oxygen. Importantly, this means that some of the DET reactions using these PCs can be performed in air without adversely affecting reaction yield.
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