New paper: Conjugation-Induced Thermally Activated Delayed Fluorescence (TADF): From Conventional Non-TADF Units to TADF-Active Polymers

In a recent collaboration with our colleagues at the Leibniz Institute of Polymer Research Dresden (IPF), we have developed polymers that show thermally activated delayed fluorescence (TADF) properties with high efficiency. This work has now been published in Advanced Functional Materials under the title: Conjugation-Induced Thermally Activated Delayed Fluorescence (TADF): From Conventional Non-TADF Units to TADF-Active Polymers. Interestingly, the monomer building block does not show TADF but rather only phosphorescence. Hence, the TADF property is induced as a consequence of increased conjugation during polymer formation. Ultimately, theĀ singlet-triplet splitting is reduced in the polymer to allow for TADF. The emitter shows sky-blue emission with roughly 70% PLQY. This report includes the synthesis of the monomer and polymer materials, quantum chemical calculations and a detailed photo-physical characterization.

Biluminescence featured in ‘Advances in Engineering’

Our work on highly efficient biluminescent organic emittersĀ at room temperature is featured in Advances in Engineering. Find the appropriate direct link here. The work describes an organic molecule, namely (BzP)PB that shows highly efficient fluorescence and phosphorescence at room temperature. Here, the intermixing between singlet and triplet manifold only determines the relative shares of fluorescence and phosphorescence, turning this emitter into a dual state emitter, where intercombination from one spin manifold to another does not represent an internal loss channel.