Cr3+-Activated Deep Trap Electron-Trapping Biphasic Mixture of Zn (Al,Ga)2O4 and Zn2GeO4 for Multilevel Information Storage by Trap Multiplexing and Wavelength Multiplexing

IF 3.2 4区化学 Q2 CHEMISTRY, ANALYTICAL

Luminescence Pub Date : 2024-11-07 DOI:10.1002/bio.70027

Zhigang Wang, Jiayu Wang, Dangli Gao, Wenqian Xu, Wenna Gao, Xiangyu Zhang, Sining Yun, Xiaojun Wang

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引用次数: 0

Abstract

Double wavelength emitting phosphors with hypersensitive thermal response are important for optical/thermal sensors and multiplexing optical data storage technology. However, it is a daunting challenge to develop multicolor electron-trapping materials with superheat sensitivity and anomalous quenching luminescence characteristics for information storage. Here, based on the selection of host lattice and the control of doping ion types, we have designed Mn²⁺- and/or Cr³⁺-activated persistent materials with excellent fluorescence properties. Among these phosphors, Mn,Cr co-activated biphasic mixture exhibits not only sensitive anomalous thermosensitive fluorescence properties but also multicolor and multimode fluorescence emission characteristics derived from Mn and Cr simultaneously. The corresponding multimode fluorescence mechanism is proposed based on afterglow energy transfer and deepening trap effect. Especially, based on the excellent fluorescence performances, these phosphors as information storage medium demonstrate multilevel information storage by a combination of the trap multiplexing and wavelength multiplexing technologies. The study here provides not only the ideas for designing and synthesizing new electronic materials but also a material foundation for the fourth generation of optical information storage and encryption.

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Cr3+ 激活的 Zn (Al,Ga)2O4 和 Zn2GeO4 深阱电子诱捕双相混合物，通过阱复用和波长复用实现多级信息存储。

具有超灵敏热响应的双波长发射荧光粉对于光学/热传感器和多路复用光学数据存储技术非常重要。然而，开发具有超热敏性和反常淬火发光特性的多色电子捕获材料用于信息存储是一项艰巨的挑战。在此，我们基于对主晶格的选择和对掺杂离子类型的控制，设计出了具有优异荧光特性的 Mn2+ 和/或 Cr3+ 激活的持久性材料。在这些荧光粉中，锰、铬共激活的双相混合物不仅具有灵敏的反常热敏荧光特性，而且同时具有锰和铬的多色和多模荧光发射特性。基于余辉能量转移和深化陷阱效应，提出了相应的多模荧光机制。特别是，基于优异的荧光性能，这些荧光粉作为信息存储介质，通过结合阱复用和波长复用技术，实现了多级信息存储。这项研究不仅为设计和合成新型电子材料提供了思路，也为第四代光信息存储和加密提供了材料基础。

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来源期刊

Luminescence 生物-生化与分子生物学

CiteScore

5.10

自引率

13.80%

发文量

248

审稿时长

3.5 months

期刊介绍： Luminescence provides a forum for the publication of original scientific papers, short communications, technical notes and reviews on fundamental and applied aspects of all forms of luminescence, including bioluminescence, chemiluminescence, electrochemiluminescence, sonoluminescence, triboluminescence, fluorescence, time-resolved fluorescence and phosphorescence. Luminescence publishes papers on assays and analytical methods, instrumentation, mechanistic and synthetic studies, basic biology and chemistry. Luminescence also publishes details of forthcoming meetings, information on new products, and book reviews. A special feature of the Journal is surveys of the recent literature on selected topics in luminescence.