Nowadays,the development of trip let-involved materials becomes a hot research topic in solid-state luminescence fields.However,the mechanism of trip let-involved emission still remains some mysteries to conquer.Here,...Nowadays,the development of trip let-involved materials becomes a hot research topic in solid-state luminescence fields.However,the mechanism of trip let-involved emission still remains some mysteries to conquer.Here,we proposed a new concept of excited-state confo rmation capture for the const ructio ns of different types of trip let-involved materials.Firstly,excited-state conformation could be trapped by supramolecular chains in crystal and fo rm a new optimum excited-state structure which is different from that in solution or simple rigid environment,leading to bright thermally activated delayed fluorescence(TADF) emission.Based on excited-state conformation capture methodology,next,we obtained roomtemperature phosphorescence(RTP) by introducing Br atoms for the enhancement of intersystem crossing.It could be concluded from experime ntal results that TADF may originate from aggregate effect while RTP may derive from monomers.Finally,heavy-atom free RTP and ultra RTP were achieved by eliminating aggregate effect.This wo rk could not only exte nd the design methodology of triplet-involved materials but also set clear evidences for the mechanism of triplet-involved emissions.展开更多
基金This work was supported by the National Natural Science Foundation of China(No.51773077).
文摘Nowadays,the development of trip let-involved materials becomes a hot research topic in solid-state luminescence fields.However,the mechanism of trip let-involved emission still remains some mysteries to conquer.Here,we proposed a new concept of excited-state confo rmation capture for the const ructio ns of different types of trip let-involved materials.Firstly,excited-state conformation could be trapped by supramolecular chains in crystal and fo rm a new optimum excited-state structure which is different from that in solution or simple rigid environment,leading to bright thermally activated delayed fluorescence(TADF) emission.Based on excited-state conformation capture methodology,next,we obtained roomtemperature phosphorescence(RTP) by introducing Br atoms for the enhancement of intersystem crossing.It could be concluded from experime ntal results that TADF may originate from aggregate effect while RTP may derive from monomers.Finally,heavy-atom free RTP and ultra RTP were achieved by eliminating aggregate effect.This wo rk could not only exte nd the design methodology of triplet-involved materials but also set clear evidences for the mechanism of triplet-involved emissions.
