(Sr3Ca4)(Ca2Ga6)O18:Mn4+: crystallographic spatial isolation enables high doping levels, exceptional antithermal quenching, and promising temperature sensing applications

IF 3.3 3区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR

Dalton Transactions Pub Date : 2025-09-19 DOI:10.1039/d5dt02222c

Yaxin Xu, Xiangxiang Jing, Jia Yang, Zien Cheng, Rihong Cong, Tao Yang, Pengfei Jiang

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引用次数: 0

Abstract

Mn4+-activated oxide phosphors have been extensively studied as promising candidates for red phosphors. However, their practical applications are significantly hindered by severe thermal quenching and the inherently low absorption capability in blue light caused by low doping concentration. In this work, we report a novel Mn4+-activated phosphor series, (Sr3Ca4)(Ca2Ga6)O18:xMn4+ (SCCGO:xMn4+), where Mn4+ emitters are confined within well-separated perovskite-like structural units, spaced more than 10.9 Å apart. This special isolation effectively suppresses concentration quenching, thus enabling a high optimal doping level of x = 0.06, an order of magnitude higher than that in perovskites. The structural confinement effect also facilitates strong coupling between the Mn4+ red-emission and the local MnO6 octahedral vibrations, thereby resulting in tunable thermal quenching (TQ) behaviors. Impressively, Mg2+-modified phosphor SCCM0.25GO:0.045Mn4+ exhibits pronounced anti-TQ behavior, retaining 142% of its room temperature emission intensity at 423 K, outperforming hitherto reported Mn4+-activated phosphors. In contrast, SCCGO:0.03Mn4+ exhibits conventional TQ performance but demonstrates exceptional relative sensitivity (Sr = 4.70 % K-1 at 200 K) and outstanding temperature resolution (δT = 0.002 K), surpassing existing lifetime-based optical thermometers. The findings highlight the effectiveness of crystallographic confinement of Mn4+ emitters as a powerful strategy for designing multifunctional, high-performance Mn4+-activated oxide phosphors with superior luminescence thermal stability and advanced thermometric sensing capabilities.

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（Sr3Ca4）（Ca2Ga6）O18:Mn4+：晶体空间隔离实现了高掺杂水平、优异的抗热淬火和有前途的温度传感应用

Mn4+活化的氧化物荧光粉作为红色荧光粉的候选材料已经被广泛研究。然而，严重的热猝灭和低掺杂浓度导致的固有的低蓝光吸收能力严重阻碍了它们的实际应用。在这项工作中，我们报告了一种新的Mn4+活化荧光粉系列，（Sr3Ca4）（Ca2Ga6）O18:xMn4+ (SCCGO:xMn4+)，其中Mn4+发射体被限制在分离良好的钙钛矿状结构单元中，间距超过10.9 Å。这种特殊的隔离有效地抑制了浓度猝灭，从而实现了x = 0.06的高最佳掺杂水平，比钙钛矿的掺杂水平高一个数量级。结构约束效应还促进了Mn4+红发射与MnO6局部八面体振动之间的强耦合，从而产生可调谐的热猝灭（TQ）行为。令人印象深刻的是，Mg2+修饰的荧光粉SCCM0.25GO:0.045Mn4+表现出明显的抗tq行为，在423 K下保持了142%的室温发射强度，优于迄今为止报道的Mn4+激活荧光粉。相比之下，SCCGO:0.03Mn4+具有传统的TQ性能，但具有卓越的相对灵敏度（200 K时Sr = 4.70% K-1）和出色的温度分辨率（δT = 0.002 K），超过了现有的基于寿命的光学温度计。该研究结果强调了Mn4+发射体晶体限制的有效性，作为设计多功能，高性能Mn4+活化氧化物荧光粉的有力策略，具有优越的发光热稳定性和先进的温度传感能力。

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来源期刊

Dalton Transactions 化学-无机化学与核化学

CiteScore

6.60

自引率

7.50%

发文量

1832

审稿时长

1.5 months

期刊介绍： Dalton Transactions is a journal for all areas of inorganic chemistry, which encompasses the organometallic, bioinorganic and materials chemistry of the elements, with applications including synthesis, catalysis, energy conversion/storage, electrical devices and medicine. Dalton Transactions welcomes high-quality, original submissions in all of these areas and more, where the advancement of knowledge in inorganic chemistry is significant.