Thermal Enhancement of Upconversion Luminescence in Negative-Thermal-Expansion Ho3+-Doped Yb2−xW3O12 Phosphors

The fluorescence intensity of lanthanide (Ln 3+ )-doped upconversion (UC) materials generally exhibits significant thermal quenching with increasing temperature, which is a critical challenge for their application. In this work, Yb 2−x W 3 O 12 :xHo phosphors with thermally enhanced UC luminescence...

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Veröffentlicht in:	Journal of electronic materials 2024-09, Vol.53 (9), p.4929-4938
Hauptverfasser:	Jin, Xiaobo, Sun, Peng, Yang, Wutao, Wang, Yijue, Xiao, Zhen
Format:	Artikel
Sprache:	eng
Schlagworte:	Characterization and Evaluation of Materials Chemistry and Materials Science Crystal lattices Diffraction patterns Electronics and Microelectronics Emission analysis Fluorescence High-Energy Battery Materials Holmium Instrumentation Lasers Luminescence Materials Science Morphology Nanomaterials Optical and Electronic Materials Phosphors Scanning electron microscopy Semiconductor lasers Sensitivity Sintering (powder metallurgy) Solid State Physics Temperature Temperature dependence Temperature measurement Thermal expansion Topical Collection: High-Energy Battery Materials Upconversion X-ray diffraction
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description	The fluorescence intensity of lanthanide (Ln 3+ )-doped upconversion (UC) materials generally exhibits significant thermal quenching with increasing temperature, which is a critical challenge for their application. In this work, Yb 2−x W 3 O 12 :xHo phosphors with thermally enhanced UC luminescence are fabricated by a facile solid-state sintering method. The x-ray diffraction (XRD) patterns reveal that the Yb 2−x W 3 O 12 :xHo samples have a pure phase, which indicates that the Ho 3+ ions are successfully doped into the crystal lattice of Yb 2 W 3 O 12 . In addition, the in situ XRD patterns show that when the temperature is increased, the diffraction peaks gradually shift to a higher angle, clearly illustrating the negative thermal expansion phenomenon of Yb 2 W 3 O 12 . The UC luminescence shows that Yb 2−x W 3 O 12 :xHo phosphors have red and green emissions when excited by a 980 nm laser diode. By changing the doping amount of Ho, it has been found that the luminescence is strongest at 2 mol%. Further investigation of the temperature-dependent upconversion emission properties of Yb 2−x W 3 O 12 :xHo samples shows that the red emission increases by several times from 323 K to 498 K. The temperature-sensing characteristics of Yb 2−x W 3 O 12 :xHo are studied using fluorescence intensity ratio (FIR)-based technology. The maximum relative sensitivity and the maximum absolute sensitivity are calculated as 2.04%/K at 323 K and 0.066/K at 498 K, respectively. These results indicate that Yb 2−x W 3 O 12 :xHo fluorescent powder can be used for optical temperature measurement.
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In this work, Yb 2−x W 3 O 12 :xHo phosphors with thermally enhanced UC luminescence are fabricated by a facile solid-state sintering method. The x-ray diffraction (XRD) patterns reveal that the Yb 2−x W 3 O 12 :xHo samples have a pure phase, which indicates that the Ho 3+ ions are successfully doped into the crystal lattice of Yb 2 W 3 O 12 . In addition, the in situ XRD patterns show that when the temperature is increased, the diffraction peaks gradually shift to a higher angle, clearly illustrating the negative thermal expansion phenomenon of Yb 2 W 3 O 12 . The UC luminescence shows that Yb 2−x W 3 O 12 :xHo phosphors have red and green emissions when excited by a 980 nm laser diode. By changing the doping amount of Ho, it has been found that the luminescence is strongest at 2 mol%. Further investigation of the temperature-dependent upconversion emission properties of Yb 2−x W 3 O 12 :xHo samples shows that the red emission increases by several times from 323 K to 498 K. The temperature-sensing characteristics of Yb 2−x W 3 O 12 :xHo are studied using fluorescence intensity ratio (FIR)-based technology. The maximum relative sensitivity and the maximum absolute sensitivity are calculated as 2.04%/K at 323 K and 0.066/K at 498 K, respectively. 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Electron. Mater</addtitle><description>The fluorescence intensity of lanthanide (Ln 3+ )-doped upconversion (UC) materials generally exhibits significant thermal quenching with increasing temperature, which is a critical challenge for their application. In this work, Yb 2−x W 3 O 12 :xHo phosphors with thermally enhanced UC luminescence are fabricated by a facile solid-state sintering method. The x-ray diffraction (XRD) patterns reveal that the Yb 2−x W 3 O 12 :xHo samples have a pure phase, which indicates that the Ho 3+ ions are successfully doped into the crystal lattice of Yb 2 W 3 O 12 . In addition, the in situ XRD patterns show that when the temperature is increased, the diffraction peaks gradually shift to a higher angle, clearly illustrating the negative thermal expansion phenomenon of Yb 2 W 3 O 12 . The UC luminescence shows that Yb 2−x W 3 O 12 :xHo phosphors have red and green emissions when excited by a 980 nm laser diode. By changing the doping amount of Ho, it has been found that the luminescence is strongest at 2 mol%. Further investigation of the temperature-dependent upconversion emission properties of Yb 2−x W 3 O 12 :xHo samples shows that the red emission increases by several times from 323 K to 498 K. The temperature-sensing characteristics of Yb 2−x W 3 O 12 :xHo are studied using fluorescence intensity ratio (FIR)-based technology. The maximum relative sensitivity and the maximum absolute sensitivity are calculated as 2.04%/K at 323 K and 0.066/K at 498 K, respectively. 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Electron. Mater</stitle><date>2024-09-01</date><risdate>2024</risdate><volume>53</volume><issue>9</issue><spage>4929</spage><epage>4938</epage><pages>4929-4938</pages><issn>0361-5235</issn><eissn>1543-186X</eissn><abstract>The fluorescence intensity of lanthanide (Ln 3+ )-doped upconversion (UC) materials generally exhibits significant thermal quenching with increasing temperature, which is a critical challenge for their application. In this work, Yb 2−x W 3 O 12 :xHo phosphors with thermally enhanced UC luminescence are fabricated by a facile solid-state sintering method. The x-ray diffraction (XRD) patterns reveal that the Yb 2−x W 3 O 12 :xHo samples have a pure phase, which indicates that the Ho 3+ ions are successfully doped into the crystal lattice of Yb 2 W 3 O 12 . In addition, the in situ XRD patterns show that when the temperature is increased, the diffraction peaks gradually shift to a higher angle, clearly illustrating the negative thermal expansion phenomenon of Yb 2 W 3 O 12 . The UC luminescence shows that Yb 2−x W 3 O 12 :xHo phosphors have red and green emissions when excited by a 980 nm laser diode. By changing the doping amount of Ho, it has been found that the luminescence is strongest at 2 mol%. Further investigation of the temperature-dependent upconversion emission properties of Yb 2−x W 3 O 12 :xHo samples shows that the red emission increases by several times from 323 K to 498 K. The temperature-sensing characteristics of Yb 2−x W 3 O 12 :xHo are studied using fluorescence intensity ratio (FIR)-based technology. The maximum relative sensitivity and the maximum absolute sensitivity are calculated as 2.04%/K at 323 K and 0.066/K at 498 K, respectively. 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subjects	Characterization and Evaluation of Materials Chemistry and Materials Science Crystal lattices Diffraction patterns Electronics and Microelectronics Emission analysis Fluorescence High-Energy Battery Materials Holmium Instrumentation Lasers Luminescence Materials Science Morphology Nanomaterials Optical and Electronic Materials Phosphors Scanning electron microscopy Semiconductor lasers Sensitivity Sintering (powder metallurgy) Solid State Physics Temperature Temperature dependence Temperature measurement Thermal expansion Topical Collection: High-Energy Battery Materials Upconversion X-ray diffraction
title	Thermal Enhancement of Upconversion Luminescence in Negative-Thermal-Expansion Ho3+-Doped Yb2−xW3O12 Phosphors
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