Single-Phase Silicate Phosphors (Ba1.3Ca0.7−xSiO4:xDy3+) Doped with Dysprosium for White Solid-State Lighting

IF 1.5 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

Advances in Condensed Matter Physics Pub Date : 2022-05-24 DOI:10.1155/2022/4317275

Desta R. Golja, Francis B. Dejene, Jung Yong Kim

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Abstract

Single-phase phosphors have potential advantages such as simple processability, competitive cost, and other optical and optoelectronic properties. Hence, in this study, the silicate phosphors (Ba_1.3Ca_0.7−xSiO₄:xDy³⁺) doped with Dy³⁺ ions (x = 0.01–0.05) were synthesized and characterized in detail. X-ray diffraction patterns showed that all the silicate phosphors have a τ-phase hexagonal unit cell independent of doping. However, d-spacing was reduced for the doped samples, indicating that the interplanar interactions were enhanced. Resultantly, the doped phosphors exhibited relatively larger domains with connectivity than the host, although there were sometimes microscale pores. Photoluminescence spectra stipulated that the optimized doping concentration is x = 0.03 for the silicate Ba_1.3Ca_0.7-xSiO₄:xDy³⁺ phosphors. Finally, the CIE coordinates (0.30, 0.33) confirm that the Dy³⁺-doped silicate phosphors are well applicable to the white light-emitting diodes for solid-state lighting and display devices.

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掺镝用于白色固态照明的单相硅酸盐荧光粉(Ba1.3Ca0.7−xSiO4:xDy3+

单相荧光粉具有简单的可加工性、具有竞争力的成本以及其他光学和光电子特性等潜在优势。因此，本研究合成了掺杂Dy3+离子(x = 0.01-0.05)的硅酸盐荧光粉(Ba1.3Ca0.7−xSiO4:xDy3+)，并对其进行了详细表征。x射线衍射图表明，所有硅酸盐荧光粉均具有τ相六方晶胞，与掺杂无关。然而，掺杂样品的d间距减小，表明面间相互作用增强。结果表明，虽然掺杂的荧光粉有时存在微孔，但其连通性比宿主体大。根据光致发光光谱，硅酸钡1.3 ca0.7 - xsio4:xDy3+荧光粉的最佳掺杂浓度为x = 0.03。最后，CIE坐标(0.30,0.33)证实了Dy3+掺杂的硅酸盐荧光粉可以很好地应用于固态照明和显示器件的白光二极管。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Advances in Condensed Matter Physics PHYSICS, CONDENSED MATTER-

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Advances in Condensed Matter Physics publishes articles on the experimental and theoretical study of the physics of materials in solid, liquid, amorphous, and exotic states. Papers consider the quantum, classical, and statistical mechanics of materials; their structure, dynamics, and phase transitions; and their magnetic, electronic, thermal, and optical properties. Submission of original research, and focused review articles, is welcomed from researchers from across the entire condensed matter physics community.

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