Non‐Rare‐Earth UVC Persistent Phosphors Enabled by Bismuth Doping

Abstract: Among various energy storage materials, long persistent phosphors (LPPs) are a class of "optical battery" that can emit luminescence continuously for a long time after the removal of excitation sources. [6] Since the report of greenemitting SrAl 2 O 4 :Eu 2+ , Dy 3+ LPPs in 1996, [7] a large variety of LPPs have been rapidly developed and widely used in security signs, displays and in vivo biological imaging, to name just a few. [8][9][10][11][12][13][14][15] Among these phosphors, representative ones with exc… Show more

“…The thermodynamic charge-transition levels (or defect levels) within the band gap correspond to the Fermi level position at which a transition occurs from one charge state ( q ) to another ( q ′). The level position ε­( q / q ′) with reference to the host VBM can be calculated by , where Δ E f ( q or q ′; E F = 0) is the formation energy of the defect in charge state q or q ′ when the Fermi level is set at 0 eV.…”

“…The thermodynamic charge-transition levels (or defect levels) within the band gap correspond to the Fermi level position at which a transition occurs from one charge state (q) to another (q′). The level position ε(q/ q′) with reference to the host VBM can be calculated by 29,30…”

Exploring Intrinsic Electron-Trapping Centers for Persistent Luminescence in Bi³⁺-Doped LiREGeO₄ (RE = Y, Sc, Lu): Mechanistic Origin from First-Principles Calculations

“…The thermodynamic charge-transition levels (or defect levels) within the band gap correspond to the Fermi level position at which a transition occurs from one charge state ( q ) to another ( q ′). The level position ε­( q / q ′) with reference to the host VBM can be calculated by , where Δ E f ( q or q ′; E F = 0) is the formation energy of the defect in charge state q or q ′ when the Fermi level is set at 0 eV.…”

“…The thermodynamic charge-transition levels (or defect levels) within the band gap correspond to the Fermi level position at which a transition occurs from one charge state (q) to another (q′). The level position ε(q/ q′) with reference to the host VBM can be calculated by 29,30…”

Exploring Intrinsic Electron-Trapping Centers for Persistent Luminescence in Bi³⁺-Doped LiREGeO₄ (RE = Y, Sc, Lu): Mechanistic Origin from First-Principles Calculations

“…The X-PersL wavelength was further shortened to around 231 nm by the same group through the theory-guided defect tuning strategy in LaPO 4 : Pr 3+ phosphors [46]. In another development, the main-group Bi 3+ ion was selected as the UVC emitter for X-PersL, which exhibited narrow afterglow peaking at 240 nm for over 2 h after ceasing X-ray irradiation [47]. These investigations create a research hotspot of high-energy UVC PersL, opening up new applications in sterilization, drug release, and cancer therapy [14,48].…”

“…After postsynthetic treatment using CaH 2 as oxygen getters, the initial intensity and duration of PersL were both improved due to the increased concentration of deep traps associated with oxygen divacancies in [PO 4 ], which was confirmed by positron annihilation lifetime spectroscopy and electron spin resonance measurements. In a subsequent study, the theoretical method was further employed to tune the intrinsic defects in YPO 4 :Bi 3+ by varying the reactant ratio, which identifies Y vacancies and Y-O vacancy complexes as the hole traps for UVC X-PersL [47].…”

Controlling X-ray-activated persistent luminescence for emerging applications

“…Bi 3+ can exhibit blue to red emission with the wavelength of 400-700 nm in an appropriate matrix. [14][15][16] BaZnGeO 4 crystallizes in the hexagonal system with a stuffed structure derived from the high-tridymite framework. The space group is P6 3 .…”

Design of a defect‐induced orange persistent luminescence phosphor BaZnGeO₄:Bi³⁺