Theoretical Study on MR-TADF Materials Based on CzBN

Abstract

Multi-resonance thermally activated delayed fluorescence (MR-TADF) materials have garnered significant research interest owing to their remarkably narrow emission spectra with full width at half maximum (FWHM) below 40~nm, demonstrating substantial advantages over conventional donor-acceptor (D--A) type TADF materials in spectral purity. However, conventional N--B--N resonant framework materials are fundamentally constrained by their intrinsically low reverse intersystem crossing rates (kRISC < 103~s-1), presenting a persistent challenge for achieving high-efficiency TADF. This study proposes a triple collaborative design strategy based on CzBN to break through this limitation: (1) Enhance the separation of HOMO and LUMO by π-conjugation expansion and reduce EST; (2) Introduce O/S heteroatoms to control the excited state charge transfer (CT) characteristics and further reduce EST; (3) Enhance the spin-orbit coupling (SOC) effect through the synergy of extended π-system and heteroatoms. Based on this, five new MR-TADF molecules were designed and studied. Among them, the kRISC of CzBN\S reached 3.48 × 106~s-1, two orders of magnitude higher than CzBN, while maintaining EST < 0.1~eV and FWHM at 40~nm.