Zhanfeng Ma, Shuo Liu, Lang Pei, Jiasong Zhong. Research Progress on Afterglow Mechanism and Application of Sr2MgSi2O7∶Eu2+,Dy3+ Long-Afterglow Phosphor[J]. Laser & Optoelectronics Progress, 2021, 58(15): 1516004
- Laser & Optoelectronics Progress
- Vol. 58, Issue 15, 1516004 (2021)
Fig. 1. Development history of inorganic long-afterglow materials
Fig. 2. Structural diagram of Sr2MgSi2O7
![Long-afterglow luminescence models. (a) Hole transfer model based on SrAl2O4∶Eu2+,Dy3+[33-34]; (b) energy transfer model based on CaAl2O4∶Eu2+,Dy3+[35]; (c) electron trap model based on aluminate and silicate[37-38]; (d) oxygen vacancy model[39-40]](/Images/icon/loading.gif){kind=icon}
Fig. 3. Long-afterglow luminescence models. (a) Hole transfer model based on SrAl2O4∶Eu2+,Dy3+[33-34]; (b) energy transfer model based on CaAl2O4∶Eu2+,Dy3+[35]; (c) electron trap model based on aluminate and silicate[37-38]; (d) oxygen vacancy model[39-40]
Fig. 4. Applications of long-afterglow materials in bio-imaging detection[61]. (a) Design diagram of design for AA detection using CoOOH-long-afterglow nanoparticles (PLNPs); (b) (c) optical image detection of AA-treated mice with CoOOH-PLNPs nanoprobe
Fig. 5. Schematic illustration of charge transfer in round-the-clock photocatalyst[67]
Fig. 6. Schematic diagram of Sr2MgSi2O7∶Eu2+,Dy3+ long-afterglow phosphor-assisted photocatalytic reaction[68]
Fig. 7. Mechanism of Sr2MgSi2O7∶Eu2+, Dy3+ involved in photocatalytic reaction process[69]. (a) Diagrams of energy-level and photogenerated electron transfer process; (b) X-ray photoelectron spectroscopy spectra of Eu 3d before and after photocatalytic reaction; (c) X-ray photoelectron spectroscopy spectra of Dy 3d and Dy 4d before photocatalytic reaction; (d) X-ray photoelectron spectroscopy spectra of Dy 3d and Dy 4d after photocatalytic reaction
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