Triphenylamine functionalized fluorenone derivative exhibiting aggregation-induced emission and multi-stimuli responsive property

Most reported stimuli-responsive luminogens with AIE properties are single-functional. Thus, developing molecules with integrated multi-responsive capabilities presents significant research potential. In this study, a triphenylamine functionalized fluorenone derivative (TPAF) with AIE property was designed and synthesized. The material exhibited multiple properties, which included mechanochromism, thermochromism, vapochromism, anti-counterfeiting, WLED, and water sensing. TPAF exhibited weak emission in its crystalline state (C-TPAF), but displayed high-contrast “turn-on” emission upon grinding, contrary to the behavior of most mechanochromic AIEgens. Furthermore, when C-TPAF was heated, a bright amorphous luminescent form of TPAF was obtained. The fluorescence and crystalline structure of C-TPAF could be fully restored through dichloromethane fumigation. This unique stimuli-responsive behavior could be repeated multiple times with minimal change. The real-time in situ fluorescence, micrographs, powder X-ray diffraction, scanning electron microscopy, and single-crystal X-ray analysis demonstrated that the multi-stimuli response of C-TPAF could be attributed to changes in molecular packing, with TPAF transitioning between crystalline and amorphous forms under external stimuli. Owing to the unique response to various stimuli of C-TPAF, a high-performance and optical data encryption was achieved using C-TPAF, which verified through changes in luminescence induced by external heat or vapor. Moreover, TPAF exhibited strong red emission in the aggregated state. A white LED device was fabricated via doping, and it demonstrated good stability. In addition, a TPAF fluorescence-based water detector demonstrated effective detection of water in organic solvents. This study provides a theoretical basis for exploring the relationship between molecular structure and performance and offers important insights for the development of high-performance, multi-stimuli responsive materials.