Uniformity improvement of a mini-LED backlight by a quantum-dot color conversion film with nonuniform thickness

Wenyan Zhang; Yu Chen; Junhu Cai; Liwen Deng; Sheng Xu; Sheng Xu; Yun Ye; Yun Ye; Qun Yan; Qun Yan; Tailiang Guo; Tailiang Guo; Enguo Chen; Enguo Chen

doi:10.1364/OL.505552

Optics Letters
Vol. 48,
Issue 21,
pp. 5643-5646
(2023)
•https://doi.org/10.1364/OL.505552

Uniformity improvement of a mini-LED backlight by a quantum-dot color conversion film with nonuniform thickness

Wenyan Zhang, Yu Chen, Junhu Cai, Liwen Deng, Sheng Xu, Yun Ye, Qun Yan, Tailiang Guo, and Enguo Chen

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Wenyan Zhang, Yu Chen, Junhu Cai, Liwen Deng, Sheng Xu, Yun Ye, Qun Yan, Tailiang Guo, and Enguo Chen, "Uniformity improvement of a mini-LED backlight by a quantum-dot color conversion film with nonuniform thickness," Opt. Lett. 48, 5643-5646 (2023)

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Table of Contents Category
- Thin Films and Other Optical Design and Fabrication
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About this Article
History
- Original Manuscript: September 11, 2023
- Revised Manuscript: September 28, 2023
- Manuscript Accepted: October 5, 2023
- Published: October 23, 2023

Abstract

Mini-LED backlights energized by quantum-dot color conversion (QDCC) hold great potential for technological breakthroughs of liquid crystal displays. However, luminance uniformity issues should still be urgently solved owing to the large interval of direct-lit mini-LEDs, especially when covering with a QDCC film (QDCCF) with uniform thickness. Herein, we propose a uniformity improvement approach of mini-LED backlights by employing a QDCCF with nonuniform thickness based on the Lambertian distribution of mini-LEDs, which is demonstrated by screen-printing preparation and ray-tracing simulation. Experimental results show that the luminance uniformity of the nonuniform QDCCF can reach 89.91%, which is 24.92% higher than the uniform one. Ray-tracing simulation further elaborates the mechanism of this significant improvement. Finally, by employing this nonuniform QDCCF, a mini-LED backlight prototype is assembled and achieves high uniformity of 92.15%, good white balance with color coordinates of (0.3482, 0.3137), and high color gamut of 109% NTSC. This work should shed some new light on mini-LED-based display technology.

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Supplementary Material (1)

Name	Description
Supplement 1	Simulation results of QD microstructure and experimental preparation

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