Induced Phase Transformation and Luminescence Performance Optimization of Li+ Doped YPO4∶Dy3+ Phosphors

doi:10.16553/j.cnki.issn1000-985x.2025.0179

Abstract

Abstract: A series of YPO₄∶Dy³⁺ phosphors with different Li⁺ doping concentrations were synthesized via a hydrothermal method combined with high-temperature calcination. The effects of Li⁺ co-doping on the structure， morphology and luminescence properties of YPO₄∶Dy³⁺ phosphors were systematically investigated. X-ray diffraction （XRD） results indicate that Li⁺ doping promotes the phase transition of YPO₄·0.8H₂O from hexagonal to tetragonal phase. Moreover， Li⁺ could either substitute Y³⁺ at lattice sites or occupy interstitial positions. Scanning electron microscopy （SEM） results show that with the increase of Li⁺ doping concentration， the morphology of the phosphor changes from hexagonal prism to spherical particles， and the average particle size gradually decreases. Fluorescence spectroscopy analysis reveals that appropriate Li⁺ doping can significantly enhance the luminescence intensity of YPO₄∶Dy³⁺ phosphors. When the Li⁺ doping amount is 5%， the luminescence intensity reaches the maximum value， which is approximately 2.3 times that of the undoped sample. Meanwhile， Li⁺ doping can also improve the thermal stability of the phosphor. With the increase of Li⁺ doping amount （x=1%~7%）， the CIE chromaticity coordinates of YPO₄∶5%Dy³⁺，xLi⁺ phosphors change gradually from （0.233， 0.283） to （0.238， 0.289）. The research results demonstrate that Li⁺ co-doping is an effective approach to regulate the luminescence properties of YPO₄∶Dy³⁺ phosphors， and provides theoretical basis and experimental foundation for their application in the field of white light-emitting diodes （LEDs）.

Key words: yttrium phosphate; alkali metal; Dy³⁺ doping; phase transition regulation; luminescence performance

CLC Number:

TQ422

ZHAN Junwei, RUAN Yongqi, CHEN Zhiqiang, WEN Lei, PENG Siyan, YANG Liusai. Induced Phase Transformation and Luminescence Performance Optimization of Li⁺ Doped YPO₄∶Dy³⁺ Phosphors[J]. Journal of Synthetic Crystals, 2025, 54(12): 2146-2155.

Figures/Tables 12

Fig.1 XRD pattern of hydrothermally synthesized precursor

Fig.2 XRD patterns of the calcined samples （a） and enlarged view of the （200） diffraction peak （b）

Table 1 Phase composition，（200） plane diffraction peak 2 θvalues， average particle size， integrated emission intensity， lifetime （ τ ）， and CIE coordinates of the calcined samples

Mole fraction of Li⁺/%	Phase composition/%		2θ/（°）	Size/nm	Emission intensity	τ/ms	CIE（x， y）
Mole fraction of Li⁺/%	Phase（h-YPO₄·0.8H₂O）	Phase（t-YPO₄）	2θ/（°）	Size/nm	Emission intensity	τ/ms	CIE（x， y）
0	37.07	62.93	26.06	600	43.8	0.534 ms	（0.229， 0.277）
1	19.06	80.94	26.10	490	62.2	0.532 ms	（0.233， 0.283）
3	0	100	26.14	430	72.3	0.526 ms	（0.235， 0.286）
5	0	100	25.94	270	100	0.514 ms	（0.236， 0.288）
7	0	100	25.86	120	83.2	0.513 ms	（0.238， 0.289）

Table 2 Lattice parameters of the calcined YPO4∶5%Dy3+，x%Li+samples

Mole fraction of Li⁺/%	a/Å	c/Å	c/a	V/Å³
JCPDS 74-2429	6.878	6.036	0.877 6	285.54
0	6.890 1（6）	6.018 9（7）	0.873 6	285.74（5）
1	6.876 1（7）	6.022 6（6）	0.875 9	284.75（6）
3	6.866 7（6）	6.025 7（4）	0.877 5	284.12（7）
5	6.869 9（5）	6.028 6（7）	0.877 5	284.52（7）
7	6.888 0（7）	6.036 5（6）	0.876 4	286.40（6）

Fig.3 SEM images of YPO4∶Dy3+ phosphors at different Li+ doping concentrations and EDS of YPO4∶5%Dy3+，5%Li+

Fig.4 FT-IR spectra of the hydrothermally synthesized samples （a） and the calcined samples （b）

Fig.5 Excitation and emission spectra of the YPO4∶5%Dy3+，5%Li+ sample

Fig.6 Emission spectra of the calcined samples （inset： variation of integrated emission intensity with Dy3+ concentration）

Fig.7 Fluorescence lifetime curve of the YPO4∶5% Dy3+，5% Li+ sample （a） and fluorescence lifetime diagram of samples with different Li+ doping concentrations （b）

Table 3 Variation values of emission intensity of calcined samples with temperature （set to 100% at 298 K）， and thermal activation energy Ea

Temperature/K	Ratio of emission intensity/%
Temperature/K	x=0	x=5%	x=7%
E_a/eV	0.159	0.167	0.158
298	100	100	100
323	96.2	97.3	96.3
348	94.5	95.7	94.4
373	91.2	93.1	91.4
398	89.1	91.5	89.4
423	86.1	89.1	86.5
448	83.7	86.9	83.9
473	80.6	84.1	81.1

Fig.8 Relationship between normalized intensity and temperature （a） and the plot of ln（I0/IT-1） versus 1/（kBT） for the determination of thermal activation energy （b）

Fig.9 CIE chromaticity diagram of the YPO4∶5%Dy3+，5%Li+ phosphor

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Induced Phase Transformation and Luminescence Performance Optimization of Li⁺ Doped YPO₄∶Dy³⁺ Phosphors

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