利用二維光子晶體探討空氣佔有率與氮化銦鎵發光二極體光萃取率之關係

Cheng-Ju Hsieh; 謝承儒

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/61997

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	管傑雄(Chieh-Hsiung Kuan)
dc.contributor.author	Cheng-Ju Hsieh	en
dc.contributor.author	謝承儒	zh_TW
dc.date.accessioned	2021-06-16T13:22:25Z	-
dc.date.available	2016-08-06
dc.date.copyright	2013-08-06
dc.date.issued	2013
dc.date.submitted	2013-07-25
dc.identifier.citation	[1] S. Ja-Yeon Kim, Min-Ki Kwon, et al., “Enhancement of light extraction from GaN-based green light-emitting diodes using selective area photonic crystal”, APPLIED PHYSICS LETTERS 96, 251103 (2010). [2] K. H. Li and H. W. Choi, “ Air-spaced GaN nanopillar photonic band gap structures patterned by nanosphere lithography”, JOURNAL OF APPLIED PHYSICS 109, 023107 (2011). [3] Keunjoo Kim, Jaeho Choi, Jong Bae Park, Sang Cheol Jeon, Jin Soo Kim, and Hee Mok Lee, “ Lattice Constant Effect of Photonic Crystals on the Light Output of Blue Light-Emitting Diodes”, IEEE PHOTONICS TECHNOLOGY LETTERS, VOL. 20, NO. 17, (2008) [4] Haiyong Gao, Fawang Yan, Yang Zhang, Jinmin Li, Yiping Zeng, et al., “ Enhancement of the light output power of InGaN/GaN light-emitting diodes grown on pyramidal patterned sapphire substrates in the micro- and nanoscale”, JOURNAL OF APPLIED PHYSICS 103, 014314 (2008). [5] Shuji Nakamura,“GaN growth using buffer layer”, JAPANESE JOURNL OF APPLIED PHYSICS, VOL. 30, NO. 10A, (1991) [6] Rolf Aidam, Elke Diwo, Nicola Rollbuhler, Lutz Kirste, and Fouad Benkhelifa, “Strain control of AlGaN/GaN high electron mobility transistor structures on silicon (111) by plasma assisted molecular beam epitaxy”, JOURNAL OF APPLIED PHYSICS 111, 114516 (2012) [7] Seshadri Kolluri, Stacia Keller, Steven P. Denbaars, Umesh K. Mishra, ” Microwave Power Performance N-Polar GaN MISHEMTs Grown by MOCVD on SiC Substrates Using an Al2O3 Etch-Stop Technology”,IEEE ELECTRON DEVICE LETTERS, VOL. 33, NO. 1(2012) [8] You-Da Lin, Matthew T. Hardy, Po Shan Hsu, Kathryn M. Kelchner, Chia-Yen Huang,Daniel A. Haeger, Robert M. Farrell, Kenji Fujito, Arpan Chakraborty, Hiroaki Ohta,James S. Speck, Steven P. DenBaars, and Shuji Nakamura,“Blue-Green InGaN/GaN Laser Diodes on Miscut m-Plane GaN Substrate”, Applied Physics Express 2,082102 (2009) [9] E. Fred Schubert,“Light-Emitting Diode”, Cambridge University Press,pp.92, 2 edition (2006) [10] Jonathan J. Wierer, Jr, Aurelien David and Mischa M. Megens,“III-nitride photonic-crystal light-emitting diodes with high extraction efﬁciency” ,NATURE PHOTONICS ，VOL 3 [11] K. H. Li and H. W. Choi, “Air-spaced GaN nanopillar photonic band gap structures patterned by nanosphere lithography”, JOURNAL OF APPLIED PHYSICS ,109, 023107(2011) [12] Wai Yuen Fu, Kenneth Kin-Yip Wong, and H. W. Choi, “Close-packed hemiellipsoid arrays: A photonic band gap structure patterned by nanosphere lithography”, APPLIED PHYSICS LETTERS ,95, 133125(2009) [13] Aurelien David, Henri Benisty, and Claude Weisbuch,“Optimization of Light-Diffracting Photonic-Crystals for High Extraction Efficiency LEDs”, JOURNAL OF DISPLAY TECHNOLOGY, VOL. 3, NO. 2(2007) [14] A. David, C. Meier, R. Sharma, F. S. Diana, S. P. DenBaars, E. Hu, S. Nakamura, and C. Weisbuch,“Photonic bands in two-dimensionally patterned multimode GaN waveguides for light extraction”, APPLIED PHYSICS LETTERS,87, 101107(2005) [15] Elison Matioli, Blaise Fleury, Elizabeth Rangel, Evelyn Hu, James Speck et al., “Measurement of extraction and absorption parameters in GaN-based photonic-crystal light-emitting diodes”, JOURNAL OF APPLIED PHYSICS 107, 053114 (2010) [16] 游耀鴻,“利用電子束微影技術於氮化鎵表面製作次波長週期結構增加發光二極體光萃取率”,國立台灣大學電子工程學系碩士論文(2012) [17] MOCVD, Wikipedia, The free encyclopedia. [18] P. Fini, X. Wu, E. J. Tarsa, Y. Golan, V. Srikant, S. Keller, S. P. Denbaars and J. S. Speck, “The Effect of Growth Environment on the Morphological and Extended Defect Evolution in GaN Grown by Metalorganic Chemical Vapor Deposition”, Japanese Journal of Applied Physics, 37,pp. 4460-4466 (1998) [19] Michael Quirk, Julian Sedra, “Semiconductor Manufacturing Technology”, Prentice Hall,Ch13~Ch15, 1st edition(2000) [20] Marianne Hiltunen, Esa Heinonen, Jussi Hiltunen, Jarkko Puustinen, Jyrki Lappalainen, and Pentti Karioja, “Nanoimprint Fabrication of Slot Waveguides” , IEEE Photonics Journal , Vol. 5, No. 2(2013) [21] Tzeng-Tsong Wu, Sheng-Yun Lo, Huei-Min Huang, Che-Wei Tsao, Tien-Chang Lu and Shing-Chung Wang, “High quality factor nonpolar GaN photonic crystal nanocavities”, APPLIED PHYSICS LETTERS, 102, 191116 (2013) [22] ELS-7500, Elionix Incoporated [23] Hong Xiao,“ Introduction to Semiconductor Manufacturing Technology ”, Ch7, Prentice Hall(2000) [24] RIE-101iph, Samco Incoporated [25] “《Electrification Dissipating Material》Espacer”, Show Denco Company [26] Nova 600i, FEI company [27] J. K. Sheu, Y. K. Su, G. C. Chi, M. J. Jou, C. C. Liu,“ Inductively coupled plasma etching of GaN using Cl2/Ar and Cl2/N2 gases”, JOURNAL OF APPLIED PHYSICS, VOLUME 85, NUMBER 3 [28] Dennis M. Manos,Daniel L. Flamm , “Plasma etching : An Introduction”, pp. 91-155,New York, ( 1989) [29] Dang Hoang Long et al., “Design Optimization of Photonic Crystal Structure for Improved Light Extraction of GaN LED”, IEEE JOURNAL OF SELECTED TOPICS IN QUANTUM ELECTRONICS, VOL. 15, NO. 4, JULY/AUGUST (2009) [30] Aurelien David, Tetsuo Fujii, Rajat Sharma, Kelly McGroddy, Shuji Nakamura, “Photonic-crystal GaN light-emitting diodes with tailored guided mode distribution”, APPLIED PHYSICS LETTERS, 88, 061124 (2006) [31] Saroj Kanta Patra, Sonachand Adhikari, and Suchandan Pal,“Design and Analysis of “Chess Board” Like Photonic Crystal Structure for Improved Light Extraction in GaN/InGaN LEDs”, Journal of Display Technology, Volume 9 ,Issue5(2013) [32] Petr G. Eliseev, Gennady A. Smolyakov, and Marek Osi’nski,“Ghost Modes and Resonant Effects in AlGaN–InGaN–GaN Lasers”, IEEE JOURNAL OF SELECTED TOPICS IN QUANTUM ELECTRONICS, VOL. 5, NO. 3(1999) [33] Chuanyu Jia, Tongjun Yu, Sen Mu, Yaobo Pan, Zhijian Yang et al.,“Polarization of edge emission from III-nitride light emitting diodes of emission wavelength from 395to455nm”, APPLIED PHYSICS LETTERS ,90, 211112(2007) [34] D.I. FLORESCU, D.S. LEE, S.M. TING, J.C. RAMER, and E.A. ARMOUR, “Edge-Emitting Electroluminescence Polarization Investigationof InGaN/GaN Light-Emitting Diodes Grown by Metal-Organic Chemical Vapor Deposition on Sapphire (0001)”, Journal of ELECTRONIC MATERIALS, Vol. 32, No.11(2003) [35] J. Shakya, K. Knabe, K. H. Kim, J. Li, J. Y. Lin et al.,“Polarization of III-nitride blue and ultraviolet light-emitting diodes”, APPLIED PHYSICS LETTERS,86, 091107(2005) [36] Chuanyu Jia, Tongjun Yu, Renchun Tao, Xiaodong Hu, Zhijian Yang et al.,“Spontaneous luminescence polarizations of wurtzite InGaN/GaN quantum wells”, APPLIED PHYSICS LETTERS,93, 171114(2008) [37] K. B. Nam, J. Li, M. L. Nakarmi, J. Y. Lin, and H. X. Jiang,“Unique optical properties of AlGaN alloys and related ultraviolet emitters”, APPLIED PHYSICS LETTERS, VOLUME 84, NUMBER 25(2004) [38] Jeong Rok Oh et al., “Effects of symmetry, shape, and structural parameters of two-dimensional SiNx photonic crystal on the extracted light from Y2O3:Eu3+film”, JOURNAL OF APPLIED PHYSICS,105, 043103 (2009)
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/61997	-
dc.description.abstract	本篇論文使用電子束微影系統以及電感耦合式電漿乾蝕刻於氮化銦鎵/氮化鎵發光二極體之P型氮化鎵上以製作光子晶體結構，探討光子晶體之空氣佔有率與發光二極體光萃取率之關係。以聚焦離子束顯微鏡確定光子晶體線寬及深度，且利用微觀光致激發螢光頻譜系統及倒立式螢光顯微鏡量測發光二極體出光強度。本論文實驗主題可分為五大部分，第一部分為調整電感耦合式電漿乾蝕刻氣體比例調整，預設蝕刻氮化鎵參數會使得蝕刻表面崎嶇不平，藉由調降氬氣流量而得到平坦蝕刻表面。第二部分為二維凸柱結構轉變至一維光柵結構，固定週期於400nm下改變空氣佔有率，且製作兩組深度150nm及180nm，兩組數據皆於空氣佔有率55%可得到最佳光萃取率。第三部分為氮化鎵發光二極體成長於雙面拋光藍寶石基板，固定週期於400nm下製作二維凸柱結構且改變空氣佔有率，使用微觀光致激發螢光顯微鏡量測是將雷射光從樣品正面打入且正面收光，其結果在空氣佔有率55%可得到最佳光萃取率，而使用倒立式螢光顯微鏡量測是將雷射光從樣品背面打入且正面收光，其結果在空氣佔有率60%可得到最佳光萃取率，其差距本論文認為是收光系統之差異所造成，故認為仍是空氣佔有率55%可得到最佳光萃取率。第四部份為二維凸柱結構之深度變化，固定週期於450nm下製作二維凸柱結構且改變空氣佔有率，製作深度範圍從150nm至780nm，共9組深度，其結果皆於空氣佔有率55%可得到最佳光萃取率，將空氣佔有率55%之各組深度之相對PL強度對深度作圖，可得到週期性變化，其週期峰值所在深度可以公式預測，其預測結果與實驗結果相近。第五部分為二維孔洞結構，固定週期於400nm及450nm下製作二維凸柱結構且改變空氣佔有率，各製作兩組深度150nm及200nm，其四組結果皆於空氣佔有率45%可得到最佳光萃取率，再將週期400nm及450nm於深度150nm之二維凸柱結構與二維孔洞結構做比較，二維凸柱結構光萃取率皆高於二微孔洞結構，最後將實驗結果以實驗室模擬成果及文獻資料來解釋其物理意義。	zh_TW
dc.description.abstract	The dissertation is focus on the fabrication of the photonic crystals on the P-type GaN of the InGaN-based light-emitting diode by electron-beam lithography and inductively coupled plasma reactive-ion etching. We study the relation between the air duty cycle and the light extraction efficiency of InGaN-based light-emitting diode. After the fabrication process of photonic crystal, we use the Focus-ion Beam to measure the line-width and the depth of the photonic cyrstals and detect the output light intensity of light emitting diode by the Micro-PL spectrum system and the inverted microscope. The main focus of the dissertation is divided into five parts. First, we adjust the recipe of the default GaN etching recipe of the inductively coupled plasma reactive-ion etching. Second, we change the two-dimensional post photonic crystals into one-dimensional photonic crystals with period at 400nm and depth at 150nm and 180nm. The two series of experiment data revel that we can get the optimized light extraction efficiency with air duty cycle at 55%. The third part is that we change the air duty cycle by altering the line-width of the two-dimensional post photonic crystals with period at 400nm and depth at 150nm on the P-type GaN of the light-emitting diode grown on the double-polished sapphire substrate. We get the optimized light extraction efficiency with air duty cycle at 55% according to the data measured by Micro-PL system, and get the optimized light extraction efficiency with air duty cycle at 60% according to the data measured by inverted microscope. The disparity of these results is due to the difference of the measurement system. The fourth part is that we change the air duty cycle by altering the line-width of the two-dimensional post photonic crystals with period at 450nm and nine different depth which is from 150nm to 780nm on the P-type GaN of the light-emitting diode. We get the optimized light extraction efficiency with air duty cycle at 55% at all the different depths. If we plot the relation between relative PL peak intensity with air duty cycle at 55% and depth, we get the periodic graph. The periodic peak of the depth could be work out by the formula, and the results of the formula are close to the results of the experiment data. The last part is that we change the air duty cycle by altering the line-width of the two-dimensional hole photonic crystals with period at 400nm and 450nm and depth at 150nm and 200nm on the P-type GaN of the light-emitting diode. These four series of data revel that we get the optimized light extraction efficiency with air duty cycle at 45%. If we compare the relative PL peak intensity between two-dimensional post photonic crystals and two-dimensional hole photonic crystals with period at 400nm and 450nm and depth at 150nm, we find that two-dimensional post photonic crystals could get the better light extraction efficiency. Finally, we describe the physical meaning of the experiment data results by the simulation results of our laboratory and some literatures.	en
dc.description.provenance	Made available in DSpace on 2021-06-16T13:22:25Z (GMT). No. of bitstreams: 1 ntu-102-R00943070-1.pdf: 9455620 bytes, checksum: 18655961d9dc70bf7d588efd62ee2b14 (MD5) Previous issue date: 2013	en
dc.description.tableofcontents	口試委員會審訂書 I 誌謝 II 摘要 III Abstract V 目錄 VII 圖表索引 IX 第一章簡介 1 1-1 研究動機 1 1-2 文獻回顧與探討 1 1-3 章節概要 2 第二章光萃取率理論與實驗室成果 4 2-1 光萃取率理論 4 2-1-1臨界角損失(Critical Angle Loss) 4 2-1-2菲涅耳損失(Fresnel Loss) 5 2-1-3材料吸收(Absorption of Material) 5 2-1-4 光子晶體(Photonic Crystal) 6 2-2 實驗室成果 7 第三章氮化鎵表面光子晶體製程與量測系統 10 3-1 氮化鎵表面光子晶體製程 10 3-1-1 金屬有機化學氣相沉積(Metal-organic Chemical Vapor Deposition ，MOCVD) 10 3-1-2 電子束微影系統(E-beam Lithography) 12 3-1-3 電感耦合式電漿乾蝕刻(Inductively Coupled Plasma Reactive Ion Etching，ICP-RIE) 13 3-1-4 二維凸柱光子晶體製程 14 3-1-5 二維孔洞光子晶體製程 17 3-1-6 一維光柵光子晶體製程 20 3-2 量測系統 21 3-2-1聚焦離子束顯微鏡(Focus Ion Beam) 21 3-2-2 微觀光致激發螢光頻譜(Micro-PL Spectrum) 22 3-2-3倒立式螢光顯微鏡(Inverted Microscope) 23 第四章實驗數據結果與討論 24 4-1 電感耦合式電漿乾蝕刻氣體比例最佳化 24 4-2 二維凸柱結構轉變至一維光柵結構 28 4-2 氮化鎵發光二極體成長於雙面拋光藍寶石基板 37 4-2-1 反射頻譜(Reflectance Spectrometer) 39 4-2-2 穿透頻譜(Transmittance Spectrometer) 40 4-4 二維孔洞結構 51 第五章總結 57 5-1 總結論 57 5-2 未來可研究方向 58 參考文獻 59
dc.language.iso	zh-TW
dc.subject	空氣佔有率	zh_TW
dc.subject	氮化銦鎵	zh_TW
dc.subject	光萃取率	zh_TW
dc.subject	光子晶體	zh_TW
dc.subject	發光二極體	zh_TW
dc.subject	air duty cycle	en
dc.subject	InGaN	en
dc.subject	light-emitting diode	en
dc.subject	photonic crystal	en
dc.subject	light extraction efficiency	en
dc.subject	air duty cycle	en
dc.subject	InGaN	en
dc.subject	light-emitting diode	en
dc.subject	photonic crystal	en
dc.subject	light extraction efficiency	en
dc.title	利用二維光子晶體探討空氣佔有率與氮化銦鎵發光二極體光萃取率之關係	zh_TW
dc.title	Utilizing Two-Dimensional Photonic Crystals to Study the Relation between the Air Duty Cycle and the Light Extraction Efficiency of InGaN-Based Light-Emitting Diode	en
dc.type	Thesis
dc.date.schoolyear	101-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	孫允武(Yuen-Wuu Suen),孫建文(Kien-Wen Sun),林瑞明(Ray-Ming Lin),吳肇欣(Chao-Hsin Wu)
dc.subject.keyword	氮化銦鎵,發光二極體,光子晶體,光萃取率,空氣佔有率,	zh_TW
dc.subject.keyword	InGaN,light-emitting diode,photonic crystal,light extraction efficiency,air duty cycle,	en
dc.relation.page	63
dc.rights.note	有償授權
dc.date.accepted	2013-07-25
dc.contributor.author-college	電機資訊學院	zh_TW
dc.contributor.author-dept	電子工程學研究所	zh_TW
顯示於系所單位：	電子工程學研究所

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