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A lumen efficiency (LE) simulation model with the Monte Carlo method is introduced to the white-light-emitting diode devices that utilize the red LED (light-emitting diode) dyes instead of red-emitting phosphors (R-WLEDs). By simulating this model, the desirable spectrum-related indices and photometric efficiencies, which are adequate for superior chromatic consistency (or Rf > 97), can be accomplished for R-WLEDs under the correlated color temperature (CCT) range of 5000–8000 K. The structure of the R-LED has LEDs in red and blue colors (650 nm and 448 nm) combined with phosphors possessing yellow and green emissions (586 nm and 507 nm). In comparison with pc-WLEDs (WLEDs operating with conversion phosphors) and QD-WLEDs (WLED devices with quantum dots), pc/R-WLED devices could present its outperformance to the others and become a promising way to achieve remarkable chromatic generation, particularly under the condition of small color temperature limit, and act as a substitute for the pc-WLED devices.
Słowa kluczowe
Wydawca
Czasopismo
Rocznik
Tom
Strony
159--169
Opis fizyczny
Bibliogr. 26 poz., rys.
Twórcy
autor
- Institute of Applied Technology, Thu Dau Mot University, Binh Duong Province, Vietnam
autor
- Faculty of Engineering and Technology, Nguyen Tat Thanh University, Ho Chi Minh City, Vietnam
autor
- Faculty of Mechanical – Electrical and Computer Engineering, School of Engineering and Technology, Van Lang University, Ho Chi Minh City, Vietnam
Bibliografia
- [1] Nguyen TMH, Ton TP, Anh NDQ. Eu-activated strontium-barium silicate: a positive solution for improving luminous efficacy and color uniformity of white light-emitting diodes. Mater Sci Pol. 2021;38:594–600.
- [2] Nguyen TMH, Ton TP, Anh NDQ, Thanh TT. Triple-layer remote phosphor structure: a novel option for the enhancement of WLEDs’ color quality and luminous flux. Mater Sci Pol. 2021;38:654–660.
- [3] Anh NDQ, Ngoc HV. Building superior lighting properties for WLEDs utilizing two-layered remote phosphor configurations. Mater Sci Pol. 2020;38:493–501.
- [4] Anh NDQ, Vinh NH, Lee H-Y. Effect of red-emitting Sr2.41F2.59B20.03O74.8:Eu0.12,Sm0.048 phosphor on color rendering index and luminous efficacy of white LEDs. Curr Opt Photon. 2017;1:118–24.
- [5] Anh NDQ, Vinh NH, Lee H-Y, Lee H-Y. Gaussian decomposition method in designing a freeform lens for an LED fishing/working lamp. Curr Opt Photon. 2017;1:233–8.
- [6] Jiang P-Q, Peng Y, Mou Y, Cheng H, Chen MX, Liu S. Thermally stable multi-color phosphor-in-glass bonded on flip-chip UV-LEDs for chromaticity-tunable WLEDs. Appl Opt. 2017;56:7921–6.
- [7] Yang X, Chai CF, Chen JC, Zheng SS, Chen C. Single 395 nm excitation warm WLED with a luminous efficiency of 104.86 lm/W and a color rendering index of 90.7. Opt Mater Express. 2019;9:4273–86.
- [8] Yuce H, Guner T, Balci S, Demir MM. Phosphor-based white LED by various glassy particles: control over luminous efficiency. Opt Lett. 2019;44:479–82.
- [9] Ton TP, Phuong LNT, Le VT, Anh NDQ, Liao H-Y, Luo G-F, et al. Enhancing color quality of WLEDs with dual-layer remote phosphor geometry. Mater Sci Pol. 2021;38:667–74.
- [10] Luo G-F, Loan NTP, Tho LV, Anh NDQ, Lee H-Y. Enhancement of color quality and luminous flux for remote-phosphor LEDs with red-emitting CaMgSi2O6:Eu2+,Mn2+. Mater Sci Pol. 2020;38:409–15.
- [11] Yang L, Zhang Q, Li F, Xie A, Mao L, Ma JD. Thermally stable lead-free phosphor in glass enhancement performance of light emitting diodes application. Appl Opt. 2019;58:4099–104.
- [12] Ding XR, Chen Q, Tang Y, Li JS, Talwar DP, Yu BH, et al. Improving the optical performance of multi-chip LEDs by using patterned phosphor configurations. Opt Express. 2018;26:A283–92.
- [13] Gao WJ, Ding K, He GX, Zhong P. Color temperature tunable phosphor-coated white LEDs with excellent photometric and colorimetric performances. Appl Opt. 2018;57:9322–7.
- [14] Zhang J, Ji BW, Hua ZH, “Investigations on the luminescence of Ba2Mg(PO4)2:Eu2+,Mn2+ phosphors for LEDs,” Opt. Mater. Express. 2016;6:3470–5.
- [15] Li J-S, Chen Y-H, Li Z-T, Yu S-D, Tang Y, Ding X-R, et al. ACU optimization of pcLEDs by combining the pulsed spray and feedback method. J Display Technol. 2016;12:1229–34.
- [16] Alzahrani JS, Alothman MA, Eke C, Ghamdi HA, Aloraini DA, Buriahi MSA. Simulating the radiation shielding properties of TeO2–Na2O–TiO glass system using PHITS Monte Carlo code. Comput Mater Sci. 2021;196:110566.
- [17] Olarinoye O, Alomairy S, Sriwunkum C, Buriahi MA. Effect of Ag2O/V2O5 substitution on the radiation shielding ability of tellurite glass system via XCOM approach and FLUKA simulations. Phys Scr. 2021;96:065308.
- [18] Buriahi MA, Tonguc BT, Perişanoğlu U, Kavaz E. The impact of Gd2O3 on nuclear safety proficiencies of TeO2–ZnO–Nb2O5 glasses: A GEANT4 Monte Carlo study. Ceram Int. 2020;46:23347–56.
- [19] Ge ZY, Piquette A, Mishra KC, Klotzkin D. Enhanced forward emission of YAG:Ce3+ phosphor with polystyrene nanosphere coating. Appl Opt. 2015;54:6025–8.
- [20] Cheng J, Zhang J, Lu J, Bian XT, Zhang HC, Shen ZH, et al. Photoluminescence properties of Ca4La6(SiO4)4(PO4)2O2-based phosphors for wLEDs. Chin Opt Lett. 2019;17:051602.
- [21] Agarwal S, Haseman MS, Khamehchi A, Saadatkia P, Winarski DJ, Selim FA. Physical and optical properties of Ce:YAG nanophosphors and transparent ceramics and observation of novel luminescence phenomenon. Opt Mater Express. 2017;7:1055–65.
- [22] Li B-C, Zhang D-W, Huang Y-S, Ni ZJ, Zhuang S-L. A new structure of multi-layer phosphor package of white LED with high efficiency. Chin Opt Lett. 2010;8:221–3.
- [23] Liu Z–Y, Liu S, Wang K, Luo X-B. Measurement and numerical studies of optical properties of YAG:Ce phosphor for white light-emitting diode packaging. Appl Opt. 2010;49:247–57.
- [24] Yen WM, Weber MJ. Inorganic phosphors: compositions, preparation and optical properties. Boca Raton, FL: CRC Press; 2004.
- [25] Liu S, Luo XB. LED packaging for lighting applications: design, manufacturing and testing. Beijing: Chemical Industry Press and John Wiley & Sons; 2011.
- [26] Davis W, Ohno Y. Color quality scale. Opt Eng. 2010;49:033602.
Typ dokumentu
Bibliografia
Identyfikator YADDA
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