Your search keyword '"Yang, Juyu"' showing total 5 results

1. Optimizing luminescence intensity and thermal stability of Gd5Si2BO13:Tb3+ through the incorporation of non-rare earth Bi3+.

Author

Xing, Xiaoyu, Liu, Yangai, Liu, Yukun, Xie, Cian, Sun, Tonglu, Yang, Chenguang, Yang, Juyu, Wang, Linlin, Mei, Lefu, and Mi, Ruiyu

Subjects

*TERBIUM, *THERMAL stability, *RARE earth ions, *LUMINESCENCE, *EXCITATION spectrum, *LIGHT emitting diodes

Abstract

Rare earth ion doped fluorescent powder, as a key material for the application of white light-emitting diodes (w-LEDs), green components often face the problem of poor thermal stability. Developing fluorescent powders with excellent thermal stability is of great significance. This article synthesized a series of Gd 5 Si 2 BO 13 :Tb3+ blue phosphors and non rare earth Bi3+ ion doped Gd 5 Si 2 BO 13 :Tb3+ green phosphors using a high-temperature solid-phase method. The phase structure and photoluminescence characteristics of the sample were analyzed in detail through XRD, excitation and emission spectra, as well as attenuation curves. The energy transfer from Bi3+ to Tb3+ was studied and confirmed through photoluminescence spectra and lifetime decay curves. Research has shown that the addition of Bi3+ significantly enhances the emission intensity of Tb3+ in the near ultraviolet range, and tunes the emission color of Gd 5 Si 2 BO 13 :Bi3+ and Tb3+ from blue to green, attributed to the energy transfer from Bi3+ to Tb3+. In addition, the addition of Bi3+ increased the thermal stability of single doped fluorescent powder Gd 5 Si 2 BO 13 :0.55Tb3+ from 88.21 % to 92.82 % at 150 °C, proving that the Gd 5 Si 2 BO 13 :Bi3+ and Tb3+ samples have good thermal stability. This study not only deepens our understanding of the new main material Gd 5 Si 2 BO 13 , but also provides a reference for the development of green phosphors with excellent thermal stability. [Display omitted] • A series of Gd 5 Si 2 BO 13 :Bi3+, Tb3+ phosphors were successfully synthesized. • The co-doped Gd 5 Si 2 BO 13 :Bi3+, Tb3+ phosphors have excellent emission intensity and thermal stability. • The Gd 5 Si 2 BO 13 :Bi3+, Tb3+ green phosphors is promising for use in high-power LED lighting devices and backlight displays. [ABSTRACT FROM AUTHOR]

Published

2024

2. A novel reddish-orange-emitting phosphor Ca3Gd7(PO4)(SiO4)5O2: Sm3+ for white light-emitting diodes.

Author

Sun, Tonglu, Liu, Danyang, Liu, Yan-Gai, Yu, Haojun, Bu, Xiaoya, Wang, Linlin, Yang, Juyu, and Mei, Lefu

Subjects

*LIGHT emitting diodes, *RARE earth ions, *ELECTRON transitions, *OPTICAL properties, *RIETVELD refinement, *PHOSPHORS, *GADOLINIUM

Abstract

Phosphor is the decisive material in white light-emitting diodes (WLED), affecting light quality. Silica phosphate has good stability, low cost and environmentally friendly features, so it has great application potential. In this paper, a self-activated reddish-orange phosphor Ca 3 Gd 7 (PO 4)(SiO 4) 5 O 2 : x Sm3+ was prepared by the high-temperature solid-phase method. The phase purity of the sample was verified by X-ray diffraction (XRD). The Rietveld refinement method was used to resolve further the sample structure and the location of the substitution of rare earth ions. The photoluminescence properties were studied in detail using fluorescence spectra, temperature-dependent emission spectra and other characterization methods. The electron transition and energy transfer processes of Gd3+ in Ca 3 Gd 7 (PO 4)(SiO 4) 5 O 2 were analyzed. The fluorescence decay curve of the sample was obtained, which belongs to the double exponential curve, and the decay lifetime depending on the Sm3+ doping concentration was calculated. Furthermore, a WLED device was assembled, and warm white light was obtained, with a spectrum showing characteristic red emission, proving to complement the missing red component of commercial WLEDs. These results indicate that Ca 3 Gd 7 (PO 4)(SiO 4) 5 O 2 : x Sm3+ phosphor has great potential for application. • The reddish-orange-Emitting phosphor Ca 3 Gd 7 (PO 4)(SiO 4) 5 O 2 : x Sm3+ was obtained via the high-temperature solid-state method. • The structure of Ca 3 Gd 7 (PO 4)(SiO 4) 5 O 2 : x Sm3+ phosphor, including the incorporation sites of Sm3+, were investigated. • The mechanism of energy transfer in the luminescence process of samples was studied. • The optical properties of Ca 3 Gd 7 (PO 4)(SiO 4) 5 O 2 : x Sm3+ reddish-orange-emitting phosphor were investigated carefully. [ABSTRACT FROM AUTHOR]

Published

2023

3. Introducing cation disorder to enhance thermal stability in LuY3(BO3)4: Eu3+ phosphors for pc-WLEDs.

Author

Yang, Chenguang, Liu, Yangai, Yu, Haojun, Liu, Yukun, Bu, Xiaoya, Yang, Juyu, Xie, Cian, and Chen, Jian

Subjects

*THERMAL stability, *PHOSPHORS, *ELECTRON emission, *RADIATIONLESS transitions, *COMPOSITE structures, *LIGHT emitting diodes

Abstract

Thermal quenching is a serious drawback that limits the application of phosphor-converted white light-emitting diodes (pc-WLEDs), because the operating temperature of phosphors tends to increase, resulting in emission loss due to non-radiative transitions. Herein,by introducing Lu3+ ions and Eu3+ ions into YBO 3 to create lattice distortion and cation disorder, a series of Lu 1-x Y 3 (BO 3) 4 : xEu3+ red phosphors have been designed to obtain novel phosphors with excellent thermal stability. The phosphors were synthesized by the traditional high-temperature solid-phase method. XRD results and EDS energy spectrum access the phase composite and crystal structure. Under 393 nm excitation, Lu 1-x Y 3 (BO 3) 4 : xEu3+ phosphors emit red light peaking at 594 nm, 613 nm, and 651 nm Lu 0.6 Y 3 (BO 3) 4 :0.4Eu3+ and Lu 0.2 Y 3 (BO 3) 4 :0.8Eu3+ can maintain 93% and 86% emission intensity respectively at 150 °C, and they can still maintain 90.2% and 78% respectively at 200 °C. Thermoluminescence spectroscopy proves that the Lu 0.2 Y 3 (BO 3) 4 :0.8Eu3+ phosphor has deep defects at 145 °C and 400 °C, which can release electrons to compensate for the emission intensity at high temperatures, thereby improving thermal stability.The prepared phosphor has extremely high thermal stability and particularly high color rendering purity (99.8%). Under the driving current of 120 mA, the color rendering index of the pc-WLED packaged with Lu 0.2 Y 3 (BO 3) 4 :0.8Eu3+ phosphor powder is 89.4, and the correlated color temperature is 4681K.All these results indicate that LuY 3 (BO 3) 4 :Eu3+ phosphors are promising for pc-WLED applications, especially for applications requiring high temperature operating conditions. • A novel red phosphor LuY 3 (BO 3) 4 :Eu3+ has been synthesized. Lu 1-x Y 3 (BO 3) 4 :xEu3+ phosphors were successfully synthesized. • Creating cation disorder and deep defects can enhance thermal stability. • The prepared phosphors have excellent thermal stability. • Lu 1-x Y 3 (BO 3) 4 :xEu3+ color purity can reach more than 99.8%. [ABSTRACT FROM AUTHOR]

Published

2022

4. A novel cyan-emitting phosphor Ba2La8(SiO4)6O2:Eu2+ for full-spectrum white light-emitting diodes.

Author

Sun, Tonglu, Liu, Danyang, Liu, Yan-Gai, Bu, Xiaoya, Yu, Haojun, Yang, Juyu, Xie, Ci-An, and Chen, Jian

Subjects

*LIGHT emitting diodes, *OPTICAL properties, *REFLECTANCE spectroscopy, *RIETVELD refinement, *FLUORESCENCE spectroscopy, *PHOSPHORS

Abstract

Phosphors are regarded as the crucial functioning part of white light-emitting diodes (WLEDs). Silicate-based phosphors have enjoyed numerous attentions for decades due to their varied crystal structures and high chemical stability, as well as their great application potentials. In this work, a novel cyan-emitting phosphor Ba 2 La 8 (SiO 4) 6 O 2 :Eu2+ is synthesized via a high-temperature solid-state method. The phase purity was first verified by X-ray diffraction (XRD) analyses, and its structure was further solved by Rietveld refinement. The photoluminescence characteristics were investigated in detail by employing diffuse reflectance spectroscopy (DRS), fluorescence spectroscopy, and other characterization methods. The results evidence that the optimal doping concentration of Eu2+ is ∼4 mol%. The fundamental band gap of Ba 2 La 8 (SiO 4) 6 O 2 :4mol%Eu2+ is estimated to be approximately 2.91 eV, which provides sufficient space to accommodate activators like Eu2+. The CIE coordinates lie in the cyan region, which allows Ba 2 La 8 (SiO 4) 6 O 2 :Eu2+ to efficiently fill into the missing cyan emission in conventional WLED devices. As a proof-of-concept experiment, a prototype WLED device was then assembled, which suggests that the introduction of Ba 2 La 8 (SiO 4) 6 O 2 :Eu2+ could lead to an increased color rendering index from 87 to 92. These results imply that the Ba 2 La 8 (SiO 4) 6 O 2 :Eu2+ phosphors show great potential in full-spectrum WLEDs application. • The novel cyan-emitting phosphor Ba 2 La 8 (SiO 4) 6 O 2 :Eu2+ was obtained via a typical high-temperature solid-state method. • The structure of Ba 2 La 8 (SiO 4) 6 O 2 :Eu2+ phosphor, including the incorporation sites of Eu2+ into the host, were investigated. • The optical properties of Ba 2 La 8 (SiO 4) 6 O 2 :Eu2+ cyan-emitting phosphor were investigated carefully. • Thanks to the additional cyan component from the Ba 2 La 8 (SiO 4) 6 O 2 :Eu2+, the color rendering index of the WLED has boosted. [ABSTRACT FROM AUTHOR]

Published

2022

5. Broadband near-infrared emission of K3ScF6:Cr3+ phosphors for night vision imaging system sources.

Author

Yu, Haojun, Chen, Jian, Mi, Ruiyu, Yang, Juyu, and Liu, Yan-gai

Subjects

*NIGHT vision, *IMAGING systems, *PHOSPHORS, *NEAR infrared radiation, *BLUE light, *LIGHT emitting diodes, *THERMAL stability

Abstract

• K 3 ScF 6 :Cr3+ can be excited by blue light, leading to a broadband NIR emission. • K 3 ScF 6 :Cr3+ retain 87.3% of their initial emission intensity at 150 °C. • The fabricated NIR-LED based on K 3 ScF 6 :Cr3+ has good photoelectric efficiency. • NIR-LED based on K 3 ScF 6 :Cr3+ can be applied in night vision imaging systems. Broadband near-infrared light (NIR) near 800 nm has broad application prospects in food detection and night vision monitoring. Compared with NIR chips, NIR phosphors have distinct advantages, including low cost, a mature synthesis process, and tunable combination. However, at present, oxide NIR phosphors have some disadvantages, such as a narrow full width at half maximum (FWHM), poor thermal stability, and low photoelectric efficiency. Herein, K 3 ScF 6 :Cr3+ NIR phosphors with a cubic structure were synthesized using the hydrothermal method. These phosphors can be effectively excited by blue light (430 nm) and red light (630 nm), leading to a broadband Cr3+ emission from 650 nm to 950 nm with a large FWHM of 430 nm. They also exhibit excellent thermal stability and retain 87.3% of their initial intensity at 150 °C. Under a driving current of 100 mA, their photoelectric efficiency can reach 9.315% of that of fabricated NIR light-emitting diodes (NIR-LED). An NIR-LED device based on this phosphor can thus be implemented in night vision imaging systems. [ABSTRACT FROM AUTHOR]

Published

2021