Various methods for deliberate design of electron and hole trapping materials were explored with a study on double lanthanide doped rare earth ortho phosphates.
The vacuum referred binding energy (VRBE)-guided design of Bi3+-based storage and afterglow materials together with charge carrier trapping processes is explored with a study on bismuth- and lanthanide-doped rare earth ortho-phosphates.
Developing a feasible
design principle for solid-state materials
for persistent luminescence and storage phosphors with high charge
carrier storage capacity remains a crucial challenge. Here we report
a methodology for such rational design via vacuum referred binding
energy (VRBE) diagram aided band structure engineering and crystal
synthesis optimization. The ARE(Si,Ge)O4 (A = Li, Na; RE
= Y, Lu) crystal system was selected as a model example. Low-temperature
(10 K) photoluminescence excitation and emission spectra of bismuth-
and lanthanide-doped ARE(Si,Ge)O4 system were first systematically
studied, and the corresponding VRBE schemes were then established.
Guided by these VRBE schemes, Bi3+ afterglow and storage
phosphor properties were explored in NaLu1–x
Y
x
GeO4. By combining
Bi3+ with Bi3+ itself or Eu3+, Bi3+ appears to act as a deep hole-trapping center, while Bi3+ and Eu3+ act as less-deep electron traps. Trap
depth tunable afterglow and storage were realized in NaLu1–x
Y
x
GeO4:0.01Bi3+ and NaLu1–x
Y
x
GeO4:0.01Bi3+,0.001Eu3+ by adjusting x, leading to conduction band engineering.
More than 28 h of persistent luminescence of Bi3+ was measurable
in NaYGeO4:0.01Bi3+ due to electron release
from Bi2+ and recombination with a hole at Bi4+. The charge carrier storage capacity in NaYGeO4:0.01Bi3+ was discovered to increase ∼7 times via optimizing
synthesis condition at 1200 °C during 24 h. The thermoluminescence
(TL) intensity of the optimized NaYGeO4:0.001Bi3+ and NaYGeO4:0.01Bi3+,0.001Eu3+ is
∼3, and ∼7 times higher than the TL of the state-of-the-art
X-ray storage phosphor BaFBr(I):Eu. Proof-of-concept color tuning
for anti-counterfeiting application was demonstrated by combining
the discovered and optimized NaYGeO4:0.01Bi3+ afterglow phosphor with perovskite CsPbBr3 and CdSe quantum
dots. Information storage application was demonstrated by UV-light-
or X-ray-charged NaYGeO4:0.01Bi3+,0.001Eu3+ phosphor dispersed in a silicone gel imaging film. This
work not only reports excellent storage phosphors but more importantly
provides a design principle that can initiate more exploration of
afterglow and storage phosphors in a designed way through combining
VRBE-scheme-guided band structure engineering and crystal synthesis
optimization.
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