Dual-mode up/down-conversion optical thermometry of Pr3+-regulated Li0.9K0.1NbO3:Er3+ phosphors

Chinese Physics Pub Date : 2023-01-01 DOI:10.7498/aps.72.20231170

None Jia Chao-Yang, None Yang Xue, None Wang Zhi-Gang, None Chai Rui-Peng, None Pang Qing, None Zhang Xiang-Yu, None Gao Dang-Li

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Abstract

Photothermal sensing is crucial for the development of smart wearable devices. However, designing and synthesizing luminescent materials with suitable multi-wavelength emission and constructing multiple sets of probes in a single material system is a huge challenge for constructing sensitive temperature sensors with a wide temperature range. In this paper, Pr³⁺, Er³⁺ single-doped and double-doped Li_0.9K_0.1NbO₃ phosphors were successfully prepared by high temperature solid phase method, and their structure, morphology, excitation wavelength and temperature-dependent fluorescence properties were characterized by XRD, SEM, fluorescence spectrometer and self-made heating device. Firstly, the photoluminescence of the synthesized series of samples was investigated. The results show that compared with the single-doped Li_0.9K_0.1NbO₃: Er³⁺sample, the up/down-conversion spectra of Pr³⁺, Er³⁺ co-doped phosphors under 808/380 nm excitation show that the green fluorescence emission of Er³⁺ is enhanced. In addition, under 980 nm excitation, Pr³⁺ can effectively regulate the fluorescence energy level population pathway, so that the electrons are more effectively arranged in the ²H_11/2 and ⁴S_3/2 energy levels during the excitation process. The red emission is weakened and the green emission is enhanced, which improves the signal resolution of the fluorescent material and has a significant impact on the optical temperature measurement. Secondly, the up-conversion fluorescence property of Er³⁺ under 808/980 nm laser excitation in Li_0.9K_0.1NbO₃:Er³⁺and Li_0.9K_0.1NbO₃:Pr³⁺,Er³⁺phosphors were investigated. The results show that the red and green fluorescence emissions of Er³⁺ are two-photon processes. Finally, the up/down-conversion dual-mode temperature sensing properties of Er³⁺ in Li_0.9K_0.1NbO₃:Er³⁺ and Li_0.9K_0.1NbO₃:Pr³⁺,Er³⁺ phosphors were investigated. It was found that both materials have good optical temperature measurement performance. Pr³⁺ doping optimizes the dual-mode optical temperature measurement performance of Li_0.9K_0.1NbO₃:Er³⁺ phosphors derived from the thermal coupling energy level of Er³⁺ions. In addition, the up/down-conversion fluorescence mechanism of Li_0.9K_0.1NbO₃:Er³⁺ and Li_0.9K_0.1NbO₃:Er³⁺,Pr³⁺ phosphors is proposed, and the enhanced green fluorescence by Pr³⁺ co-doping is attributed to the energy transfer from Pr³⁺ to Er³⁺ ions, leading to the increase of green fluorescence level population and the decrease of red fluorescence level population of the Er³⁺ ions. This new dual-mode optical temperature measurement material provides a material basis and optical temperature measurement technology for exploring other temperature measurement materials.

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Pr3+调节Li0.9K0.1NbO3 Er3+荧光粉

光热传感对于智能可穿戴设备的发展至关重要。然而，设计和合成具有合适的多波长发射的发光材料，并在单一材料体系中构建多组探头，对于构建宽温度范围的敏感温度传感器是一个巨大的挑战。摘要Pr 3 + & lt; / sup> Er 3 + & lt; / sup>单掺杂和双掺杂Li0.9K0.1NbO3采用高温固相法成功制备了荧光粉，并利用XRD、SEM、荧光光谱仪和自制加热装置对其结构、形貌、激发波长和温度依赖性荧光性质进行了表征。首先，研究了合成的系列样品的光致发光性能。结果表明:与单掺杂的Li0.9K0.1 nbo>3 3+样品相比，Pr3+共掺杂荧光粉在808/380 nm激发下，Er3+<是增强。此外，在980 nm激发下，Pr3+能有效调节荧光能级居子通路，使电子更有效地排列在2H11/2和& lt; sup> 4 & lt; / sup> S 3/2激发过程中的能级。红光发射减弱，绿光发射增强，提高了荧光材料的信号分辨率，对光学测温有重要影响。其次，Er3+在808/980 nm激光激发下，对Li0.9K0.1 nbo>3+ Er< 3+K0.1 nbo>3+ Pr3+ Er3+ Er3+进行了研究。结果表明，Er3+都是双光子过程。最后，对Er3+在Li 0.9 & lt; / sub> K 0.1 & lt; / sub> NbO 3 & lt; / sub>: Er 3 + & lt; / sup>和Li 0.9 & lt; / sub> K 0.1 & lt; / sub> NbO 3 & lt; / sub>: Pr 3 + & lt; / sup> Er 3 + & lt; / sup>对荧光粉进行了研究。结果表明，两种材料均具有良好的光学测温性能。Pr 3 + & lt; / sup>掺杂优化了Li0.9K0.1NbO3 Er3+来源于Er3+离子热耦合能级的荧光粉。此外，Li0.9K0.1NbO3 Er3+和Li 0.9 & lt; / sub> K 0.1 & lt; / sub> NbO 3 & lt; / sub>: Er 3 + & lt; / sup> Pr 3 + & lt; / sup>采用Pr3+共掺杂归因于Pr3+Er 3 + & lt; / sup>，导致Er3+离子。这种新型双模光学测温材料为探索其他测温材料提供了物质基础和光学测温技术。

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Chinese Physics

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Dual-mode up/down-conversion optical thermometry of Pr<sup>3+</sup>-regulated Li<sub>0.9</sub>K<sub>0.1</sub>NbO<sub>3</sub>:Er<sup>3+</sup> phosphors

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