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双离子取代(MeY)(AlSi)O:Eu石榴石荧光粉:组合筛选、还原退火及发光性能

Dual-ion substituted (MeY)(AlSi)O:Eu garnet phosphors: combinatorial screening, reductive annealing, and luminescence property.

作者信息

Zheng Zhehan, Deng Mingxue, Wang Caiyan, Zhang Xiang, Liu Qian, Xu Xiaoke, Gao Le

机构信息

The State Key Laboratory of High Performance Ceramics and Superfine Microstructure, Shanghai Institute of Ceramics, Chinese Academy of Sciences Shanghai 200050 China

College of Materials Science and Engineering, Fuzhou University Fuzhou Fujian 350116 China.

出版信息

RSC Adv. 2021 Jun 22;11(36):22034-22042. doi: 10.1039/d1ra02705k. eCollection 2021 Jun 21.

DOI:10.1039/d1ra02705k
PMID:35480845
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9034095/
Abstract

In recent years, the efficiency of combinatorial methods has been utilized to accelerate the finding or screening of inorganic materials. In this work, based on the double substitution strategy of the cation ions Me/Si, a series of Me Y Al Si O:Eu garnet phosphors (MeYASG:Eu, Me = Mg, Ca, Sr, Ba) were rapidly prepared and screened by a combinatorial method in microreactor arrays. Through parallel experiments of solid-state synthesis, the reliability of the combinatorial screening was verified and an optimal composition of CaYAlSiO:Eu (CYASG:Eu) with advanced luminous intensity was obtained. Annealing experiments under air and reductive atmospheres were performed and demonstrated the controllability and reversibility of the Eu ↔ Eu valence transition process, thus realizing the tuning of the dominant emission from divalent Eu or trivalent Eu. The optimal CYASG:Eu sample showed excellent thermal quenching resistance after annealing at 800 °C for 1 h in a reducing atmosphere. The abnormal intensity of PL increased by 10% in the 50-100 °C region, and retained 63% of the initial value at 250 °C. With the assistance of thermoluminescence characterization, the complementary effect of the release of captured electrons or charge carriers in trap levels on the abnormal increase of PL intensity during the high-temperature luminescence process was revealed. By combination of the double substitution strategy of cations and annealing, a new approach is proposed to creating the coexistence of activator Eu ions with a mixed-valence state. Also, the prepared CYASG:Eu phosphors have promising applications in fields such as plant light supplements in greenhouses and plant factories and as luminescent materials for energy-saving light sources.

摘要

近年来,组合方法的效率已被用于加速无机材料的发现或筛选。在这项工作中,基于阳离子Me/Si的双重取代策略,通过微反应器阵列中的组合方法快速制备并筛选了一系列MeYAlSiO:Eu石榴石荧光粉(MeYASG:Eu,Me = Mg、Ca、Sr、Ba)。通过固态合成的平行实验,验证了组合筛选的可靠性,并获得了具有先进发光强度的CaYAlSiO:Eu(CYASG:Eu)的最佳组成。进行了空气和还原气氛下的退火实验,证明了Eu↔Eu价态转变过程的可控性和可逆性,从而实现了二价Eu或三价Eu主导发射的调谐。最佳的CYASG:Eu样品在还原气氛中于800℃退火1小时后表现出优异的抗热猝灭性能。PL的异常强度在50-100℃区域增加了10%,在250℃时保留了初始值的63%。借助热发光表征,揭示了陷阱能级中捕获电子或电荷载流子的释放对高温发光过程中PL强度异常增加的互补作用。通过阳离子的双重取代策略与退火相结合,提出了一种创造具有混合价态的激活剂Eu离子共存状态的新方法。此外,所制备的CYASG:Eu荧光粉在温室和植物工厂中的植物光补充以及作为节能光源的发光材料等领域具有广阔的应用前景。

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本文引用的文献

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