Preparation and Upconversion Luminescence Study of Rare Earth Yb3+/Tm3+ Doped NaGd（MO4）2 Phosphors

doi:10.19894/j.issn.1000-0518.220104

Chinese Journal of Applied Chemistry ›› 2023, Vol. 40 ›› Issue (3): 374-379.DOI: 10.19894/j.issn.1000-0518.220104

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Preparation and Upconversion Luminescence Study of Rare Earth Yb³⁺/Tm³⁺ Doped NaGd（MO₄）₂ Phosphors

Peng BU¹, Hong-Liang LI²()

^1.Department of Criminal Science and Technology，Hunan Police College，Changsha 410138，China
^2.Chemistry and Chemicl Engineering of Central South University，Changsha 410083，China

Received:2022-04-02 Accepted:2022-11-08 Published:2023-03-01 Online:2023-03-27
Contact: Hong-Liang LI
About author:2991770329@qq.com
Supported by:
the Scientific Research Project of the Eclucation Department of Hunan Province(19C0714)

Abstract

Abstract:

In recent years， rare-earth-doped up-conversion luminescent materials have received increasing attention in solar cells， industrial lighting， and medical fields. The current research is mainly to find new and efficient rare-earth up-conversion luminescent materials. For the study of luminescent materials， the choice of matrix is particularly important. Molybdate stands out from many matrixes due to its stable physical and chemical properties and low phonon energy. In this paper， molybdate is selected as the matrix material doped with rare earth ions. Tm and Yb ion-doped NaGd（MoO₄）₂ samples are prepared by hydrothermal method， and the change of the luminescence characteristics of NaGd（MoO₄）₂ phosphor is explored by changing the ion doping concentration. Through the analysis of its spectrum， it is found that under 980 nm laser irradiation， NaGd（MO₄）₂∶Yb³⁺/Tm³⁺ has a blue emission peak at 477 nm and a red emission peak at 648 nm. When the doping mole fraction of fixed Yb³⁺ is 6% and the doping mole fraction of Tm³⁺ is changed to 0， 0.5%， 1% and 2% respectively， it is found that with the increase of the doping mole fraction of Tm³⁺， the intensity of the emission peak at 477 nm first increases and then decreases. When the doping mole fraction of Tm³⁺ is 0.5%， the luminous intensity of molybdate phosphor first increases and then decreases to the maximum. It has broad prospects in the application of multi-color lighting and light source devices.

Key words: Rare earth doping, Molybdate, Up-conversion luminescence, Micromorphology

CLC Number:

O614.3

Peng BU, Hong-Liang LI. Preparation and Upconversion Luminescence Study of Rare Earth Yb³⁺/Tm³⁺ Doped NaGd（MO₄）₂ Phosphors[J]. Chinese Journal of Applied Chemistry, 2023, 40(3): 374-379.

Figures/Tables 7

Fig.1 XRD patterns of NaGd（MoO4）2 samples under different doping concentrations

Table 1 Unit cell parameters of Tm/Yb doped NaGd（MoO4）2

Cell parameters	a/nm	b/nm	c/nm	V/nm³
NaGd（MO₄）₂	0.524 875	0.524 875	1.147 8	31.620 5
NaGd（MO₄）₂∶6Yb/0Tm	0.523 305	0.523 305	1.140 7	32.237 8
NaGd（MO₄）₂∶6Yb/0.5Tm	0.523 243	0.523 243	1.140 6	32.228 9
NaGd（MO₄）₂∶6Yb/1Tm	0.523 007	0.523 007	1.140 9	31.208 5
NaGd（MO₄）₂∶6Yb/2Tm	0.522 981	0.522 981	1.141 6	31.224 5

Fig.2 SEM images of NaGd（MoO4）2 samples under different doping concentrations

Fig.3 Emission spectra of NaGd（MO4）2∶Yb3+/Tm3+ phosphors at 400~700 nm， excitation light at 980 nm NaGd（MO4）2∶6%Yb，0Tm， NaGd（MO4）2∶W6%Yb，0.5%Tm， NaGd（MO4）2∶6%Yb，1%Tm， NaGd（MO4）2∶6%Yb，2%Tm

Fig.4 Chromaticity diagram of NaGd （MO4）2∶Yb3+/Tm3+ Phosphor

Table 2 Color coordinates of Tm/Yb doped NaGd（MoO4）2

Sample	Color coordinates（x，y）
（a） NaGd（MO₄）₂∶6Yb/0Tm	（0.265 3，0.174 2）
（b） NaGd（MO₄）₂∶6Yb/0.5Tm	（0.214 2，0.124 4）
（c） NaGd（MO₄）₂∶6Yb/1Tm	（0.238 5，0.153 9）
（d） NaGd（MO₄）₂∶6Yb/2Tm	（0.279 3，0.150 2）

Fig.5 Energy level transition diagram of Tm3+

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Preparation and Upconversion Luminescence Study of Rare Earth Yb³⁺/Tm³⁺ Doped NaGd（MO₄）₂ Phosphors

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