Structural Control of Highly Efficient Thermally Activated Delayed Fluorescence in Carbene Zinc(II) Dithiolates**
Mousree Mitra, Ondřej Mrózek, Markus Putscher, Jasper Guhl, Benjamin Hupp, Andrey Belyaev, Christel M. Marian, Andreas Steffen
Abstract
Abstract Luminescent metal complexes based on earth abundant elements are a valuable target to substitute 4d/5d transition metal complexes as triplet emitters in advanced photonic applications. Whereas Cu I complexes have been thoroughly investigated in the last two decades for this purpose, no structure‐property‐relationships for efficient luminescence involving triplet excited states from Zn II complexes are established. Herein, we report on the design of monomeric carbene zinc(II) dithiolates (CZT) featuring a donor‐acceptor‐motif that leads to highly efficient thermally activated delayed fluorescence (TADF) with for Zn II compounds unprecedented radiative rate constants k TADF =1.2×10 6 s −1 at 297 K. Our high‐level DFT/MRCI calculations revealed that the relative orientation of the ligands involved in the ligand‐to‐ligand charge transfer ( 1/3 LLCT) states is paramount to control the TADF process. Specifically, a dihedral angle of 36–40° leads to very efficient reverse intersystem‐crossing (rISC) on the order of 10 9 s −1 due to spin‐orbit coupling (SOC) mediated by the sulfur atoms in combination with a small ΔE S1‐T1 of ca. 56 meV.