Energy Transfer between Tb3+ and Eu3+ in LaPO4: Pulsed versus Switched‐off Continuous Wave Excitation

Luo, Yuxia; Liu, Zhenyu; Wong, Hock Tsen; Zhou, Lei; Wong, Ka‐Leung; Shiu, Kwok Keung; Tanner, Peter A.

doi:10.1002/advs.201900487

Cited by 23 publications

(17 citation statements)

References 54 publications

(109 reference statements)

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“…The results show that only the Y‐T model can well fit the decay curves of Tb 3+ (Figure 2 f) and simultaneously the obtained physical parameters are meaningful (Table S10). It indicates that the slow EM process between donor Tb 3+ plays a leading role in Tb 3+ ‐Sm 3+ ET dynamics and similar phenomenon is also observed in Tb 3+ , Eu 3+ doped LaPO 4 nanocrystals [40] . Moreover, the main Tb 3+ ‐Sm 3+ ET mechanism is electric dipole‐dipole (EDD) interaction, the microparameter C DA for Tb 3+ ‐Sm 3+ ET process is ≈7.203×10 −52 m 6 s −1 and the microparameter C DD for Tb 3+ ‐Tb 3+ EM process is ≈3.134×10 −54 m 6 s −1 .…”

Section: Resultssupporting

confidence: 62%

“…As shown in Figure S9, the luminescence decay curves of donor Tb 3+ ions gradually drop faster and the corresponding lifetime values decrease from ≈588 to ≈301 μs with the increase of Eu 3+ ions, which confirm the depopulation of Tb 3+ excited states by CRET process from Tb 3+ to Eu 3+ ions. Furthermore, it's well studied that the main mechanism of Tb 3+ ‐Eu 3+ CRET process is electric dipole‐dipole (EDD) interaction and the dominant CRET channel is [ 5 D 4 (Tb 3+ ), 7 F 0, 1 (Eu 3+ ) → 7 F 4 (Tb 3+ ), 5 D 0 (Eu 3+ )] (Figure S10) [38–40] . As for Tb x Sm z ‐BTC ( x =0.70, z =0–0.10) samples, under the host excitation the green emission of “sounding” Tb 3+ is dominant while that of “silent” Sm 3+ is negligible (Figure 2 e), which results from the differential sensitization effect of host.…”

Section: Resultsmentioning

confidence: 97%

“…It indicates that the slow EM process between donor Tb 3+ plays al eading role in Tb 3+ -Sm 3+ ET dynamics and similar phenomenon is also observed in Tb 3+ ,E u 3+ doped LaPO 4 nanocrystals. [40] Moreover,t he main Tb 3+ -Sm 3+ ET mechanism is electric dipole-dipole (EDD) interaction, the microparameter C DA for Tb 3+ -Sm 3+ ET process is % 7.203 10 À52 m 6 s À1 and the microparameter C DD for Tb 3+ -Tb 3+ EM process is % 3.134 10 À54 m 6 s À1 .S ee Figure S13…”

Section: Resultsmentioning

confidence: 98%

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Host Differential Sensitization toward Color/Lifetime‐Tuned Lanthanide Coordination Polymers for Optical Multiplexing

Zhou

Zhu

et al. 2020

Angewandte Chemie

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Optical multiplexing based on luminescent materials with tunable color/lifetime has potential applications in information storage and security. However, the available tunable luminescent materials reported so far still suffer from several drawbacks of low efficiency or poor stability, thus restraining their further applications. Herein, we demonstrate a strategy to develop efficient and stable lanthanide coordination polymers (LCPs) with tunable luminescence as a new option for optical multiplexing. Their multicolor emission from green to red and naked‐eye‐sensitive green emission with tunable lifetime (from ca. 300 to ca. 600 μs) can be controlled by host differential sensitization and energy transfer between lanthanide ions. The quantum efficiencies of developed samples range from around 20 % to 46 % and the luminescence intensity/lifetime appear quite stable in polar solvents up to ten weeks. Furthermore, with the aid of inkjet printing and concepts of luminescence lifetime imaging and time‐gated imaging, we illustrate their promising applications of information storage and security in spatial and temporal domains.

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Section: Resultssupporting

confidence: 62%

Section: Resultsmentioning

confidence: 97%

Section: Resultsmentioning

confidence: 98%

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Host Differential Sensitization toward Color/Lifetime‐Tuned Lanthanide Coordination Polymers for Optical Multiplexing

Zhou

Zhu

et al. 2020

Angewandte Chemie

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“…Considering that the energy difference between spin-allowed and spin-forbidden 4f-5d transitions of Tb 3 + is usually 1.0 eV, [14] bands Ca nd Dc an be assigned to Tb 3 + spin-forbidden 4f-5d J excitations with its5 d electrons in the high-spin (HS) state. The excitation peaks from 300 to 400 nm are assigned to 7 inset. Upon 376 nm excitation,t he sample demonstrates intense green light emission,s uggesting its potential application as ag reen light phosphor in WLED devices.…”

Section: Luminescence Properties Of Eu 3 + + In Ncsomentioning

confidence: 99%

“…[5] More importantly,T b 3 + can serve as a sensitizer to widen the Eu 3 + absorption through ET,f urther enhancing the luminescent intensity of Eu 3 + . [6,7] However,i ti si mperative to elucidate the ET mechanism through theoretical analysis.…”

Section: Introductionmentioning

confidence: 99%

Mechanistic Insight into Energy‐Transfer Dynamics and Color Tunability of Na₄CaSi₃O₉:Tb³⁺,Eu³⁺ for Warm White LEDs

Huang

et al. 2020

Chemistry A European J

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In this work, al atent energy-transfer process in traditional Eu 3 + ,Tb 3 + -doped phosphorsi sp roposed and a new class of Eu 3 + ,Tb 3 + -doped Na 4 CaSi 3 O 9 (NCSO) phosphors is presentedw hich is enabled by luminescence decay dynamics that optimize the electron-transfer energy process. Relative to other Eu 3 + ,Tb 3 + -doped phosphors, the as-synthesized Eu 3 + ,Tb 3 + -doped NCSO phosphors show improved large-scale tunable emission color from green to red upon UV excitation,c ontrolled by the Tb 3 + /Eu 3 + doping ratio. Detailed spectroscopicm easurements in the vacuum ultraviolet (VUV)/UV/Vis region were used to determine the Eu 3 + -O 2À charge-transfer energy,4 f-5d transition energies, andt he energies of 4f excited multiplets of Eu 3 + and Tb 3 + with different 4f N electronic configurations. The Tb 3 + !Eu 3 + energy-transfer pathway in the co-doped sample was systematically investigated, by employing luminescence decay dynamics analysist oe lucidate the relevant energy-transfer mechanism in combination with the appropriate model simulation. To demonstrate their application potential, ap rototypew hitelight-emitting diode (WLED) device was successfully fabricated by using the yellow luminescence NCSO:0.03Tb 3 + , 0.05Eu 3 + phosphor with high thermal stabilitya nd aB a-MgAl 10 O 17 :Eu 2 + phosphor in combination with an ear-UV chip. These findings open up an ew avenuet or ealize and develop multifunctional high-performancep hosphors by manipulating the energy-transfer process forp ractical applications.

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Recent Progress in Functional Dye‐Doped Liquid Crystal Devices

Shen

Zhang

Miao

et al. 2022

Adv Funct Materials

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As a typical representative of dopants, organic functional dyes have demonstrated their significant roles in novel smart liquid crystal (LC) devices, and dye-doped LCs have also been a source of inspiration for scientists to design and fabricate stimuli-gated materials or devices for envisioned applications in a wide range of areas. In this review, the focus on dichroic dyes, fluorescent dyes, and photothermal dyes, and the recent progress of the LC devices employing these dyes as dopants are overviewed. The review highlights the developments of the novel LC devices doped with these dyes. The structures, designs, and applications of these devices are outlined. The underlying principles of dichroic dyes, fluorescent dyes, and photothermal dyes which are utilized as functional dopants in LC devices are first introduced. Subsequently, the novel developments of functional dye-doped LC devices in the application fields of smart windows, attenuators for augmented reality (AR) systems, color-changeable textiles, dichroic color filters, dual-mode circular polarizers, chirality detectors, optical limiters, switchable luminescent solar concentrators, multiple information encryption, anti-counterfeiting, photo-addressed transparent displays, circularly polarized luminescence, tunable lasers, and light-driven soft actuators are discussed. Finally, the challenge and the strategies for the future improvement of dye-doped LC devices are also discussed.

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Energy Transfer between Tb³⁺ and Eu³⁺ in LaPO₄: Pulsed versus Switched‐off Continuous Wave Excitation

Cited by 23 publications

References 54 publications

Host Differential Sensitization toward Color/Lifetime‐Tuned Lanthanide Coordination Polymers for Optical Multiplexing

Host Differential Sensitization toward Color/Lifetime‐Tuned Lanthanide Coordination Polymers for Optical Multiplexing

Mechanistic Insight into Energy‐Transfer Dynamics and Color Tunability of Na₄CaSi₃O₉:Tb³⁺,Eu³⁺ for Warm White LEDs

Recent Progress in Functional Dye‐Doped Liquid Crystal Devices

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Energy Transfer between Tb3+ and Eu3+ in LaPO4: Pulsed versus Switched‐off Continuous Wave Excitation

Cited by 23 publications

References 54 publications

Host Differential Sensitization toward Color/Lifetime‐Tuned Lanthanide Coordination Polymers for Optical Multiplexing

Host Differential Sensitization toward Color/Lifetime‐Tuned Lanthanide Coordination Polymers for Optical Multiplexing

Mechanistic Insight into Energy‐Transfer Dynamics and Color Tunability of Na4CaSi3O9:Tb3+,Eu3+ for Warm White LEDs

Recent Progress in Functional Dye‐Doped Liquid Crystal Devices

Contact Info

Product

Resources

About

Energy Transfer between Tb³⁺ and Eu³⁺ in LaPO₄: Pulsed versus Switched‐off Continuous Wave Excitation

Mechanistic Insight into Energy‐Transfer Dynamics and Color Tunability of Na₄CaSi₃O₉:Tb³⁺,Eu³⁺ for Warm White LEDs