Correlating O-deficiency and luminescence property of Tb3+ doped SrO

Advanced Powder Materials Pub Date : 2023-07-01 DOI:10.1016/j.apmate.2023.100112

Kaina Wang , Jipeng Fu , Shuqin Chang , Xuan Sun , Tianyi Sun , Su Zhang , Ran Pang , Lihong Jiang , Xiaojun Kuang , Evan Wenbo Zhao , Chengyu Li , Shiqing Xu , Mingxue Tang

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引用次数: 4

Abstract

Cubic rock salt can lower down or break the rare earth transition barrier through interstitial or vacancy defects owing to its great deformation and rotation flexibility. Here, we demonstrate that oxygen vacancies in SrO are induced by proper oxidization and atmosphere adjustment, resulting in defects with various depths and crystal field distortion. The thermally assisted tunneling from defects to ⁵D₄ state and electronic population decrease on ⁵D₃ state of Tb³⁺ are observed by the deformation of adjacent oxygen octahedral structure. Finally, the as-prepared SrO: 0.01 Tb³⁺ phosphors, commercial BaMgAl₁₀O₁₇: Eu²⁺ blue phosphor, and CaAlSiN₃: Eu²⁺ red phosphor are mixed and coated onto 280 nm deep-ultraviolet LED chip to assemble white light-emitting LED device. The LEDs show CCT of 3850 K, 4136 K, and 4741 K, with color rendering index of 90.3, 90.8, and 92.1, respectively. These insights will advance the fundamental knowledge of crystal engineering in cubic rock salt, and enable new ways to manipulate energy transfer and electronic transition via defects.

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Tb3+掺杂SrO的o缺乏与发光性能的关系

立方岩盐由于其巨大的变形和旋转灵活性，可以通过间隙或空位缺陷降低或破坏稀土过渡势垒。在这里，我们证明了SrO中的氧空位是由适当的氧化和气氛调节引起的，导致不同深度的缺陷和晶体场畸变。通过相邻氧八面体结构的变形，观察到Tb3+从缺陷到5D4态的热辅助隧穿和在5D3态的电子布居减少。最后，制备的SrO:0.01将Tb3+磷光体、商用BaMgAl10O17:Eu2+蓝色磷光体和CaAlSiN3:Eu2+红色磷光体混合并涂覆到280上nm深紫外LED芯片组装白光发光LED器件。LED显示3850的CCTK、 4136K、和4741K、显色指数分别为90.3、90.8和92.1。这些见解将推进立方岩盐晶体工程的基础知识，并为通过缺陷操纵能量转移和电子跃迁提供新的方法。

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来源期刊

Advanced Powder Materials

CiteScore

33.30

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0.00%

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