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浓度和泵浦功率介导的颜色可调性、光热效应及温度传感:铒/镱/锂共掺杂的ZnGaO荧光粉中红色发射的热载流子发光中心

Concentration and pump power-mediated color tunability, optical heating and temperature sensing TCLs of red emission in an Er/Yb/Li co-doped ZnGaO phosphor.

作者信息

Yadav Ram Sagar, Bahadur Amresh, Rai Shyam Bahadur

机构信息

Laser & Spectroscopy Laboratory, Department of Physics, Institute of Science, Banaras Hindu University Varanasi 221005 India

Department of Zoology, Institute of Science, Banaras Hindu University Varanasi 221005 India

出版信息

RSC Adv. 2019 Dec 3;9(68):40092-40108. doi: 10.1039/c9ra09120c. eCollection 2019 Dec 2.

DOI:10.1039/c9ra09120c
PMID:35541369
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9076210/
Abstract

Intense red upconversion luminescence was observed in the Er/Yb/Li co-doped ZnGaO phosphor synthesized through the solid state reaction method for the first time. The structural characterization showed a large crystalline nature and an increase in the particle size Li doping. The absorption spectra showed a large number of peaks in the UV-vis-NIR regions due to the Er and Yb ions. The Er/Yb co-doped ZnGaO phosphor exhibited green, red and NIR upconversion emissions on excitation with 980 nm radiation. The intensity of the red emission was relatively larger than that of the other emissions. The luminescence intensity pump power measurements revealed the number of required photons for these emissions. The phosphor showed very interesting color tunability as a function of Er ion concentration and incident pump power. The luminescence intensity of the Er/Yb co-doped phosphor was enhanced more than two times Li doping. The enhancement in the luminescence intensity was proposed to be due to the increase in the crystallinity and particle size of the phosphor. The lifetimes of the S and F levels also increased in the presence of Li ions. The variation in the fluorescence intensity ratio (FIR) of the thermally coupled levels (TCLs) of the red emission with incident pump power offered effective optical heating in the phosphor. The temperature-induced FIR using TCLs of red emission exhibited a larger value of temperature sensing sensitivity in the presence of Li ions, which was up to 14 × 10 K. Thus, the Er/Yb/Li co-doped ZnGaO phosphor may be used in photonic, optical heating, and temperature sensing devices.

摘要

首次通过固态反应法合成的Er/Yb/Li共掺杂ZnGaO荧光粉中观察到强烈的红色上转换发光。结构表征表明,由于Li掺杂,其具有较大的结晶性且粒径增大。吸收光谱显示,由于Er和Yb离子,在紫外-可见-近红外区域有大量峰。Er/Yb共掺杂ZnGaO荧光粉在980 nm辐射激发下呈现绿色、红色和近红外上转换发射。红色发射的强度相对大于其他发射的强度。发光强度与泵浦功率的测量揭示了这些发射所需的光子数。该荧光粉作为Er离子浓度和入射泵浦功率的函数表现出非常有趣的颜色可调性。Li掺杂使Er/Yb共掺杂荧光粉的发光强度提高了两倍多。发光强度的增强被认为是由于荧光粉结晶度和粒径的增加。在Li离子存在下,S和F能级的寿命也增加。红色发射的热耦合能级(TCLs)的荧光强度比(FIR)随入射泵浦功率的变化在荧光粉中提供了有效的光热效应。利用红色发射的TCLs进行温度诱导的FIR在Li离子存在下表现出更大的温度传感灵敏度值,高达14×10 K。因此,Er/Yb/Li共掺杂ZnGaO荧光粉可用于光子、光热和温度传感器件。

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