A Synergistic Enhancement Strategy for Realizing Ultralong and Efficient Room-Temperature Phosphorescence.

Reported here is a synergistic enhancement strategy for realizing ultralong bright room-temperature phosphorescence (RTP), involving polymerization between phosphor monomers and acrylamide and host-guest complexation interaction between phosphors and cucurbit[6, 7, 8]urils (CB[6, 7, 8]). The non-phosphorescent monomers exhibit 2.46 s ultralong lifetime after copolymerizing with acrylamide. The immense improvement is because of the rich hydrogen bond and carbonyl within the polymers which promote intersystem crossing (ISC), suppress nonradiative relaxation and shield quenchers effectively. By tuning the ratio of chromophores, a series of phosphorescent copolymers with different lifetimes and quantum yields are prepared. Significantly, the complexation of macrocyclic hosts CB[6, 7, 8] promote the RTP of polymers by blocking aggregation-caused quenching (ACQ), and offsetting the losses of aforementioned interaction provided by polymer. Moreover, multiple lifetime-encoding for digit and character encryption are achieved by utilizing the difference of their lifetimes, demonstrating great potential in anti-counterfeiting. This synergistic enhancement strategy provides a new approach for realizing high-performance RTP.