A multicolor‐emitted phosphor for temperature sensing and multimode dynamic anti‐counterfeiting

Tang, Yixian; Deng, Mingxue; Zhou, Zhenhua; Wang, Yuandong; Liu, Qian

doi:10.1111/jace.18587

Cited by 9 publications

(5 citation statements)

References 44 publications

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“…Luminescent materials show wide-ranging application prospects in light-emitting devices, [1][2][3][4] anti-counterfeiting, 5,6 biological imaging, 7,8 and optical information storage. 9 However, the emission intensity of most luminescent materials is evidently reduced under the temperature range of 373 to 473 K compared to the initial state, which greatly limits their applications under high temperatures up to 473 K. The emission loss with increasing temperature is known as the thermal quenching (TQ) effect, [10][11][12] one of the greatest obstacles to extend the commercial applications of existing materials. [13][14][15] The TQ results in significant increase of non-radiation distribution of excited state electrons of luminescent ions.…”

Section: Introductionmentioning

confidence: 99%

Gradient defects mediate negative thermal quenching in phosphors

et al. 2023

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Luminescent materials often suffer from thermal quenching (TQ), limiting the continuation of their applications under high temperatures up to 473 K. The formation of defect levels could suppress TQ, but rational synthesis and deep understanding of multiple defects-regulated luminescent materials working in such a wide temperature range still remain challenging. Here, we prepare a negative thermal quenching (NTQ) phosphor LiTaO 3 ∶Tb 3þ by introducing gradient defects V 5− Ta , Tb 2þ Li , and ðV Ta Tb Li Þ 3− as identified by advanced experimental and theoretical studies. Its photoluminescence significantly becomes intense with rising temperatures and then slowly increases at 373 to 473 K. The mechanism studies reveal that gradient defects with varied trapping depths could act as energy buffer layers to effectively capture the carriers. Under thermal disturbance, the stored carriers could successively migrate to the activators in consecutive and wide temperature zones, compensating for TQ to enhance luminescence emission. This study initiates the synthesis of multi-defect NTQ phosphors for temperature-dependent applications.

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Section: Introductionmentioning

confidence: 99%

Gradient defects mediate negative thermal quenching in phosphors

et al. 2023

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Section: Discussionmentioning

confidence: 99%

“…Recently, our team reported a multicolor‐emitting phosphor Ba 0.99 Ga 2 O 4 :0.01Bi 3+ , which could be applied in dynamic anti‐counterfeiting. [ 98 ] The realization of multiple anti‐counterfeiting modes is attributed to the different emission centers of Bi ions and the presence of Ga vacancies. Figure a shows that the photoluminescence color of the Ba 0.99 Ga 2 O 4 :0.01Bi 3+ turns from yellow at room temperature to orange at high temperatures.…”

Section: Potential Applications Of Bi‐activated Persistent Phosphorsmentioning

confidence: 99%

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Bismuth‐Activated Persistent Phosphors

Tang

Deng

Wang

et al. 2022

Advanced Optical Materials

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“…successfully prepared a novel material with abundant trap energy levels by selectively doping Bi 3+ into the MgGa 2 O 4 matrix (MgGa 2 O 4 :Bi 3+ ). [ 114 ] Due to the high defect density of Bi doping, multiple trap levels with continuous distribution exist in MgGa 2 O 4 :Bi 3+ , where deep traps are essential for information storage. Different luminance information is demonstrated at room temperature and at high temperature of 200°C as depicted in Figure 6c, which directly demonstrates the optical information reading and writing capability of the material.…”

Section: Anti‐counterfeiting Application Of Persl With Double or Mult...mentioning

confidence: 99%

Anti‐Counterfeiting Application of Persistent Luminescence Materials and Its Research Progress

Zhang,

Wang,

Huo

et al. 2023

Laser & Photonics Reviews

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Persistent luminescent materials can continue to emit light after stopping excitation, and their stored energy is gradually released during the decay time after persistent emitting, which makes the color and luminance changes in slow decay and plays an important role in protecting information and combating forgery. When combined with other anti‐counterfeiting technologies to form a multi‐modal and multi‐process anti‐counterfeiting design, it perfectly hides the real information and has a broad application prospect in anti‐counterfeiting logo design. A brief overview of the design of three different persistent luminescence‐based anti‐counterfeiting applications in unimodality to achieve information encryption in the time dimension. The energy stored in the trap is studied to be released by different physical stimuli and applied to stimulus‐like responsive persistent luminescent materials, and the design of persistent luminescence anti‐counterfeiting applications based on many different processes in dual‐modality, obtaining the dynamic anti‐counterfeiting effect of multiple processes in multiple modes. This work reviews the research background of persistent luminescent materials in the field of anti‐counterfeiting in recent years, compares the important breakthrough progress of persistent luminescent materials applied to anti‐counterfeiting research, and finally puts forward the current problems, future challenges, and development directions.

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A multicolor‐emitted phosphor for temperature sensing and multimode dynamic anti‐counterfeiting

Cited by 9 publications

References 44 publications

Gradient defects mediate negative thermal quenching in phosphors

Gradient defects mediate negative thermal quenching in phosphors

Bismuth‐Activated Persistent Phosphors

Anti‐Counterfeiting Application of Persistent Luminescence Materials and Its Research Progress

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