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  • 學位論文

旋塗式玻璃微透鏡應用在紫外光發光二極體取光效率提升

Extraction efficiency enhancement in ultra-violet LEDs based on spin on glass microlenses

劉奇旻(Chi-Min Liu)
指導教授 : 蘇國棟
國立臺灣大學/電機資訊學院/光電工程學研究所/碩士(2015年)
https://doi.org/10.6342/NTU.2015.02463
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摘要

本論文中我們提出一個低成本的製程方法將旋塗式玻璃微透鏡製作至紫外光發光二極體上。旋塗式玻璃微透鏡是利用光阻熱處理及多次翻模技術製程,這能有效的降低製程成本。在我們的實驗中,我們製作了不同直徑大小的旋塗式玻璃微透鏡,分別有200, 150, 100及50微米的直徑,並且得到光萃取率提升分別為7.31%, 10.35%, 14.01% 及21.86%。同時,我們也製作了不同形狀的微透鏡,分別有圓形、正方形及六角形,並且得到光萃取率提升分別為7.31%, 9.6%及13.8%。我們利用透鏡圖形的優化,實驗上能有效地將光萃取率提升至21.86%,並且不會破壞任何紫外光發光二極體的電性。

關鍵字

微透鏡 旋塗式玻璃 紫外光發光二極體 光萃取率 多次翻模製程

並列摘要

In this paper, we present a cost-effective method to fabricate spin on glass microlens array (SOG MLA) on ultra-violet light emitting diodes (UV LEDs). SOG microlens array was formed by thermal reflow technique and multiple replication processes which can reduce the cost of solution process. In our experiments, we fabricated different diameter size SOG microlens arrays whose diameter of each size was about 200, 150, 100 and 50 μm. The light extraction efficiency is improved by 7.31%, 10.35%, 14.01% and 21.86%, respectively. We also fabricated the different shape SOG microlenses, which was circular, square and hexagonal. The light extraction efficiency is improved by 7.31%, 9.6% and 13.8% for circular, square and hexagonal SOG MLA, respectively. By applying optimized lens pattern, an increase of 21.86% in improved light extraction efficiency is achieved experimentally, without detrimental effect to the electrical performance of the UV LEDs.

並列關鍵字

spin on glass microlens array ultra-violet light emitting diode light extraction efficiency replication process

參考文獻

[1] K. Naessens, H. Ottevaere, R. B H. Ottevaere, R. Cox, H. P. Herzig, T. Miyashita, K. Naessens, M. Taghizadeh, R. Völkel, H. J. Woo and H. Thienpont, “Comparing glass and plastic refractive microlenses fabricated with different technologies,” Journal of Optics A: Pure and Applied Optics, vol. 8, pp. S407-S429, 2006.
[2] Z. D. Popovic, R. A. Sprague, and G. A. N. Connell, “Technique for monolithic fabrication of microlens arrays,” Applied Optics, vol. 46, pp. 1281-1284, 1988.
[3] D. Daly, R. F. Stevens, M. C. Hutley, and N. Davies, “The manufacture of microlenses by melting photoresist,” Measurement Science and Technology, vol. 1, pp. 759-766, 1990.
[4] T. R. Jay and M. B. Stern, “Preshaping photoresist for refractive microlens fabrication”, Optical Engineering, vol. 33, pp. 3552-3555, 1994.
[5] H. Ottevaere, B. Volckaerts, M. Vervaeke, P. Vynck, A. Hermanne, H. Thienpont, “Plastic microlens arrays by deep lithography with protons: fabrication and characterization,” in Proceedings Symposium IEEE/LEOS Benelux Chapter, pp. 281-284, 2003.

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