Long persistent phosphors—from fundamentals to applications

Abstract: Owing to the unique mechanism of photoelectron storage and release, long persistent phosphorescence, also called long persistent luminescence or long lasting afterglow/phosphorescence, plays a pivotal role in the areas of spectroscopy, photochemistry, photonics and materials science. In recent years, more research has focused on the manipulation of the morphology, operational wavebands and persistent duration of long persistent phosphors (LPPs). These desired achievements stimulated the growing interest in des… Show more

“…ultraviolet or X-ray). 16,20 Unlike that, the PersL excitation spectrum in Fig. 4d demonstrates the efficient activation of PersL in LCMSGO:Ce…”

“…[6][7][8][9] Recently, this approach was revealed as applicable for phosphors (an insulator in nature) as well, endowing them with PersL properties, [10][11][12][13][14][15] which opens up a brand-new perspective for exploring novel phosphorescent materials that are highly desirable in security signs, night displays, optical storage media, etc. [16][17][18][19][20] PersL is an interesting phenomenon whereby luminescence from an active center still lasts for a long period after ceasing the excitation. 16 However, there is some complex and profound physics behind the PersL mechanism, including excitation, delocalization, migration, storage, release, and recombination of charge carriers, which casts a veil of mystery over it.…”

“…[16][17][18][19][20] PersL is an interesting phenomenon whereby luminescence from an active center still lasts for a long period after ceasing the excitation. 16 However, there is some complex and profound physics behind the PersL mechanism, including excitation, delocalization, migration, storage, release, and recombination of charge carriers, which casts a veil of mystery over it. Especially, the trap properties (including the species, depth, concentration and distribution) that determine PersL behavior in a host are difficult to be identified and modulated.…”

Lu₂CaMg₂(Si_1−xGe_x)₃O₁₂:Ce³⁺solid-solution phosphors: bandgap engineering for blue-light activated afterglow applicable to AC-LED

“…ultraviolet or X-ray). 16,20 Unlike that, the PersL excitation spectrum in Fig. 4d demonstrates the efficient activation of PersL in LCMSGO:Ce…”

“…[6][7][8][9] Recently, this approach was revealed as applicable for phosphors (an insulator in nature) as well, endowing them with PersL properties, [10][11][12][13][14][15] which opens up a brand-new perspective for exploring novel phosphorescent materials that are highly desirable in security signs, night displays, optical storage media, etc. [16][17][18][19][20] PersL is an interesting phenomenon whereby luminescence from an active center still lasts for a long period after ceasing the excitation. 16 However, there is some complex and profound physics behind the PersL mechanism, including excitation, delocalization, migration, storage, release, and recombination of charge carriers, which casts a veil of mystery over it.…”

“…[16][17][18][19][20] PersL is an interesting phenomenon whereby luminescence from an active center still lasts for a long period after ceasing the excitation. 16 However, there is some complex and profound physics behind the PersL mechanism, including excitation, delocalization, migration, storage, release, and recombination of charge carriers, which casts a veil of mystery over it. Especially, the trap properties (including the species, depth, concentration and distribution) that determine PersL behavior in a host are difficult to be identified and modulated.…”

Lu₂CaMg₂(Si_1−xGe_x)₃O₁₂:Ce³⁺solid-solution phosphors: bandgap engineering for blue-light activated afterglow applicable to AC-LED

“…As mentioned above, excitation and emissions in the NIR are of particular interest, since they are located in the biological windows in which the absorption and self-fluorescence of many biological tissues are avoided [257]. Moreover, deeper penetration depth into biological tissues, better image contrast and reduced phototoxicity and photobleaching are observed [258].…”

“…The energy band engineering model ( Figure 13C) Figure 13D) [283]. However, it should be taken into account that there is no universal mechanism that explains the persistent luminescence and this is still an open topic in the scientific community [257,283,287]. Eu 2+ is the lanthanide cation most commonly used for persistent luminescence [288].…”

Rare earth based nanostructured materials: synthesis, functionalization, properties and bioimaging and biosensing applications

Luminescence