Förster Resonance Energy Transfer: An Efficient Way to Develop Stimulus-Responsive Room-Temperature Phosphorescence Materials and Their Applications

“…Besides crystal engineering, the development of host–guest doping system was also an efficient way to realize ultralong RTP emission. [ 47–51 ] In 2017, Kabe and Adachi successfully realized a long persistent luminescence more than 1 h in a host–guest doping system, which could be even comparable to the most outstanding inorganic phosphors (Figure 7A). [ 47 ] In their system, the host material of PPT acted as electron donor and guest of TMB as electron acceptor.…”

“…On the other hand, Li and coworkers innovatively utilized the distance‐sensitive Förster resonance energy transfer (FRET) to develop efficient RTP system with stimulus‐response characteristic (Figure 7C). [ 50 ] In their system, the DMAP with rigid crystal environment was selected as host/energy donor, and Cdp with potential RTP emission acted as guest/energy acceptor. As shown in Figure 7C, although no obvious RTP emission could be observed for individual DMAP or Cdp sample, their cocrystal with mass ratio of 100:1 presented ultralong green phosphorescence.…”

Organic luminescent materials: The concentration on aggregates from aggregation‐induced emission

“…Besides crystal engineering, the development of host–guest doping system was also an efficient way to realize ultralong RTP emission. [ 47–51 ] In 2017, Kabe and Adachi successfully realized a long persistent luminescence more than 1 h in a host–guest doping system, which could be even comparable to the most outstanding inorganic phosphors (Figure 7A). [ 47 ] In their system, the host material of PPT acted as electron donor and guest of TMB as electron acceptor.…”

“…On the other hand, Li and coworkers innovatively utilized the distance‐sensitive Förster resonance energy transfer (FRET) to develop efficient RTP system with stimulus‐response characteristic (Figure 7C). [ 50 ] In their system, the DMAP with rigid crystal environment was selected as host/energy donor, and Cdp with potential RTP emission acted as guest/energy acceptor. As shown in Figure 7C, although no obvious RTP emission could be observed for individual DMAP or Cdp sample, their cocrystal with mass ratio of 100:1 presented ultralong green phosphorescence.…”

Organic luminescent materials: The concentration on aggregates from aggregation‐induced emission

“…[24][25][26][27][28][29] In 2020, our group innovatively utilized the distancesensitive Förster resonance energy transfer process in the development of stimulus-responsive RTP system, in which, N,N-dimethylpyridin-4-amine (DMAP) with rigid crystal environment was selected as host/energy donor, and di-(naphthalen-2-yl)-amine (Cdp) with potential RTP emission acted as guest/energy acceptor. 30 Based on its unique heating/force-responsive RTP effect, the application of encrypted thermal printing was realized for the first time. For this RTP system, there was still room for further improvement in some aspects: such as moderate RTP efficiency (4.04%) and lifetime (768 ms), single luminous color.…”

Host–guest materials with room temperature phosphorescence: Tunable emission color and thermal printing patterns

“…Generally, long afterglow materials can avoid the use of FLI system, and are more suitable to be utilized in lifetime‐regulated luminescence anti‐counterfeiting. [ 45–49,51–58 ] Lin's group developed a kind of pure CDs‐based long afterglow materials with dual‐emissive property of fluorescence and room temperature phosphorescence (RTP) by a facile and quick microwave‐assisted process. [ 49 ] The aqueous solution of CDs was directly used as anti‐counterfeiting ink to print the portrait of Chairman Mao on a banknote as anti‐counterfeiting label.…”

Luminescence anti‐counterfeiting: From elementary to advanced