製成不同像素尺寸的紅色無稀土螢光材料薄膜之研究

Yi-Shan Lin; 林儀姍

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/78873

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	林清富(Ching-Fuh Lin)
dc.contributor.author	Yi-Shan Lin	en
dc.contributor.author	林儀姍	zh_TW
dc.date.accessioned	2021-07-11T15:25:44Z	-
dc.date.available	2025-08-18
dc.date.copyright	2020-09-23
dc.date.issued	2020
dc.date.submitted	2020-08-18
dc.identifier.citation	[1] T. A. Edison, “Electric lamp”, U.S. Patent 223898, 1880. (June 20, 2020) [2] M. Kazimierczuk and W. Szaraniec, 'Electronic ballast for fluorescent lamps', IEEE Transactions on Power Electronics, vol.8, pp.386-395. (June 17, 2020) [3] C. R. Ronda, 'Phosphors for lamps and displays: an applicational view', Journal of Alloys and Compounds 225, pp.534-538. (June 19, 2020) [4] http://www.ycctek.com/TechnicalArticle/tabid/2169/EntryId/627/-6-RGB.aspx (June 18, 2020 ) [5] H. J .Round, “A note on carborundum. Electrical world ”,vol.49, pp.309. (June 8, 2020) [6] E. F .Schubert, T .Gessmann, and J. K. Kim, 'Light emitting diodes'. (Wiley Online Library, 2005). (June 18, 2020) [7] Shunsuke Fujita, Akihiko Sakamoto and Setsuhisa Tanabe, “Luminescence Characteristics of YAG Glass–Ceramic Phosphor for White LED”, IEEE Journal of Selected Topics in Quantum Electronics, vol.14, pp.1387-1391. (June 21, 2020) [8] M. G. Craford, “High Power LEDs for Solid State Lighting”, Light Visual Environment, vol.32, pp.58-62. (June 23, 2020) [9] T. Baumgartner, et al, “Lighting the way:Perspective on the global lighting market”, McKinsey and Company, pp.22. (July 6, 2020) [10] W. M. Yen and M. J. Weber, Inorganic Phosphors: Composition, Preparation and Optical Properties, CRC Press, pp.5-8. (June 25, 2020) [11] Yuan-Chih, LinMaths Karlsson, Marco Bettinelli, “Inorganic Phosphor Materials for Lighting”, Topics in Current Chemistry, vol.3, pp.1-47. (June 27, 2020) [12] K. D. Chaudhuri, “Concentration quenching of fluorescence in solutions”, Zeitschrift für Physik, vol.154, pp.34-42. (June 28, 2020) [13] X. Peng, H. Chen, D. R. Draney, W. M. Volcheck, “A Non-fluorescent, Broad Range Quencher Dye for FRET Assays”, Analytical Biochemistry, vol.388, pp. 220-228. (July 1, 2020) [14] https://www.ch.ntu.edu.tw/~rsliu/teaching/pdf96/material/4_report.pdf (July 8, 2020) [15] B. D. Grant, N. J. Clecak and R. J. Twieg, “Deep UV photoresists I. Meldrum's diazo sensitizer”, IEEE Transactions on Electron Devices, vol.28, pp.1300-1305. (June 26, 2020) [16] Congjun Wang, Moonsub Shim and Philippe Guyot-Sionnest, “Electrochromic Nanocrystal Quantum Dots”, Science, vol.291, pp.2390-2392. (June 23, 2020) [17] R. D. Schaller, M. Sykora, J. M. Pietryga and V. I. Klimov, 'Seven excitons at a cost of one: Redefining the limits for conversion efficiency of photons into charge carriers', Nano Lett., vol. 6, no. 424. (June 29, 2020) [18] Maureen A Walling, Jennifer A Novak and Jason R. E Shepard, “Quantum Dots for Live Cell and In Vivo Imaging”, Int. J. Mol. Sci., vol.10, pp.441-449. (June 29, 2020) [19] B. M. Krasovitskii et al., Organic Luminescent Materials, Analytica Chimica Acta, vol.233, pp.336-337. (June 23, 2020) [20] K. M. Lee et al., “Emission characteristics of inorganic/organic hybrid white-light phosphor”, Appl. Phys, vol.80, pp.337-339. (June 28, 2020) [21] Y C Kang, I W Lenggoro, S B Park, et al, “YAG: Ce phosphor particles prepared by ultrasonic spray pyrolysis”, Mater Res Bull, Vol. 35, pp. 789-798. (July 3, 2020) [22] L Mancic, K Marinkovic, B A Marinkovic, et al. “YAG: Ce nanostructured particles obtained via spray pyrolysis of polymeric precursor solution,” J Eur Ceram Soc, Vol. 30, pp. 577-582. (July 3, 2020) [23] P. Smet, A. Parmentier and D. Poelman, “Selecting Conversion Phosphors for White Light-Emitting Diodes”, J. Electrochem. Soc., vol. 158, p.R37-54. (July 1, 2020) [24] https://www.slideshare.net/OSRAMLEDlight/osram-os-led-fundamentalsbasics-of-ledsv1090110 (June 26, 2020) [25] B. Wei, Y. Li, H. Li, J. Yu, B. Ye and T. Liang, 'Rare earth elements in human hair from a mining area of China', Ecotoxicology and Environmental Safety, vol.96, pp.118-123. (June 27, 2020) [26] J. Paul, G. Campbell, “Investigating rare earth element mine development in EPA region 8 and potential environmental impacts”, Additional review by Region 8, pp.14-18, 2011. (June 23, 2020) [27] https://kknews.cc/news/gyxr9m.html (July 7, 2020) [28] 蔡宗祐, “利用無稀土元素製作高效率發光材料及應用”, 國立臺灣大學光電工程學研究所碩士論文, 2017年7月. [29] 林峻宇, “高效率無稀土螢光材料及微螢光陣列之應用”, 國立臺灣大學光電工程學研究所碩士論文, 2018年7月. [30] IUPAC, Compendium of Chemical Terminology, 2nd ed. (the 'Gold Book') (1997) [31] M. A. Baldo, D. F. O’Brien, Y. You, A. Shoustikov, S. Sibley, M. E.Thompson, S. R. Forrest, Nature 1998, 395, 151. [32] https://chem.libretexts.org/Bookshelves/Physical_and_Theoretical_Chemistry_Textbook_Maps/Supplemental_Modules_(Physical_and_Theoretical_Chemistry)/Fundamentals/Dexter_Energy_Transfer (July 5, 2020) [33] O. Witt, 'Das Chrysoïdin und seine Umsetzungen', Berichte der deutschen chemischen Gesellschaft, vol.10, pp.654-662. (June 18, 2020) [34] H. Scheer, “An overview of chlorophylls and bacteriochlorophylls: biochemistry, biophysics, functions and applications”, Advances in Photosynthesis and Respiration, vol 25, pp.1-26, 2006. (June 20, 2020) [35] P. Shapley, “Absorbing light with organic molecules” , 2012. [http://butane.chem.uiuc.edu/pshapley/GenChem2/B2/1.html] (June 29, 2020) [36] 邢其毅等，“基礎有機化學第三版下冊”，“北京：高等教育出版社”，頁165，2005年. [37] Lucilla Levi and Thomas J. J. Mu¨ller, “Multicomponent syntheses of functional chromophores”, Royal Society of Chemistry, vol.45, pp.2825-2846, 2016. (July 6, 2020) [38] Raymond F.Chen, Jay R.Knutson, “Mechanism of fluorescence concentration quenching of carboxyfluorescein in liposomes: Energy transfer to nonfluorescent dimers”, Analytical Biochemistry, vol.172, pp.61-77, 1988. (July 1, 2020) [39] T. Laird, “Solvents and Solvent Effects in Organic Chemistry, Organic Process Research Development”, vol.15, pp.1213-1213, 2011. (June 16, 2020) [40] Albert M. Brouwer, “Standards for photoluminescence quantum yield measurements in solution”, Pure and Applied Chemistry, vol.83, pp. 2213–2228, 2011. (June 17, 2020) [41] 陳冠妤, “應用於白光LED之高量子產率無稀土螢光材料”, 國立臺灣大學光電工程學研究所碩士論文, 2015年6月. [42] https://leo.diytrade.com/sdp/81784/3/pd-91522/20397533-45815/400%E7%B3%BB%E5%88%97-%E9%9B%B6%E4%BB%B6%E6%B8%85%E6%B4%97%E6%A9%9F.html (June 30, 2020) [43] https://www.suss.com/tw/products-solutions/mask-aligner/mjb4 (June 30, 2020) [44] https://plasma.oxinst.com/campaigns/technology/reactive-ion-etching (June 30, 2020) [45] https://jascoinc.com/products/spectroscopy/uv-visible-nir-spectrophotometers/models/v-770-uv-visible-nir-spectrophotometer/ (June 30, 2020) [46] https://www.perkinelmer.com/product/spectrum-two-ft-ir-sp10-software-l160000a (June 30, 2020) [47] http://www.chemicalbook.com/ChemicalProductProperty_EN_CB4209342.htm (June 28, 2020) [48] Kallum M. Koczkur, Stefanos Mourdikoudis, Lakshminarayana Polavarapu, Sara E. Skrabalak, “Polyvinylpyrrolidone (PVP) in nanoparticle synthesis”, Royal Society of Chemistry, vol.44, pp.17883-17905, 2015. (June 29, 2020) [49] Lakowicz, Joseph R. “Principles of Fluorescence Spectroscopy”, (Kluwer Academic / Plenum Publishers 1999) p.10. (June 8, 2020) [50] C.H. Chen and C.W. Tang, Chem. Of Functional Dyes,Vol.2. ,2020 [51] C.H. Chen, C.W. Tang, J. Shi, K.P. Klubek, Thin Solid Films, 336,327, (2000) [52] https://www.tcichemicals.com/TW/zh_TW/p/D4700 (June 20, 2020) [53] https://www.ccp.com.tw/ccpprdt.nsf/0/658C558FF9085CA248257E900011B09C/$FILE/PVB%E6%96%B0%E7%89%88%E7%9B%AE%E9%8C%84.pdf (June 23, 2020) [54] https://www.itsfun.com.tw/%E7%A9%8D%E5%88%86%E7%90%83/wiki-9975171-6492261 (June 30, 2020)
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/78873	-
dc.description.abstract	光主宰了人類的夜生活，照明設備的開發也大大提升了人類的活動範圍及生活品質，造就了科技與文明的進步。現今的人們人手一機、一筆電、一平板，回到家中又有超大尺寸的電視可欣賞節目，隨處可見的顯示器、顯示屏幕，而這些吸引我們目光的發光元件在它被製造的過程中，我們的環境卻要付出慘痛的代價，人類的身心健康也受到了影響，因為此高效率發光元件的材料含有稀土元素或重金屬元素，而本論文將會提出一種不使用稀土元素及重金屬元素之的材料製造出高效率的螢光薄膜，其能降低製造成本，也有望解決巨量轉移的良率問題及轉移速率問題。本論文的最終結果是做出微米級的高效率紅色螢光陣列，實驗一開始是先從多種紅色有機螢光染料中選取一種適合的螢光客體染料，也就是DCJTB作為我們這次實驗的有機螢光染料。確定有機螢光染料後，我們開始嘗試使用多種不同的溶劑與DCJTB及PVP混合去製作出螢光溶液，使用積分球以藍光LED光源激發量測放光光譜並計算量子效率。使用溶液態最佳量子效率配方進行薄膜的製程，調整不同的旋塗參數製程出平整的薄膜並烤乾，並量測其量子效率及吸收率。目前以PVP為主體的製程結果所計算出最佳的薄膜的量子效率為85%。使用PVP作為薄膜主體材料的過程中，我們發現此高分子材料是親水性的，對未來製程陣列的過程中會有困難，因此尋找了新的薄膜主體材料PVB替代，在尋找的新材料的同時，我們嘗試使用UV封裝技術測試PVP為主體的螢光薄膜在大氣的環境下能保存多久，並與沒有封裝的薄膜做比較。研究的第二階段是以PVB作為薄膜主體材料進行薄膜製程，同樣先找出DCJTB與PVB混合的溶劑並量測放光光譜及計算量子效率，找到良好的旋塗參數製程平整的薄膜並開始製程陣列。而目前以PVB為主體的製程結果所計算出最佳的薄膜的量子效率為89%，吸收率為41%。陣列的製程中我們嘗試了曝光參數及氣體蝕刻參數，讓最終的陣列可得到一完整的長方體且與我們製程時所使用的光罩尺寸一致，尺寸大小有60μm20μm及6μm2μm兩種。未來我們想要在同一片基板上呈現出RGB三種顏色，藍光LED為基底以光致發光激發綠色螢光陣列及紅光螢光陣列，藉由控制藍光LED的亮度混合出不同顏色，達成全彩的微米級像素製作。	zh_TW
dc.description.abstract	Light has dominated human’s nightlife and the invention of lighting device has greatly increased the scope of human activities and the quality of life, resulting in improvement in technology and civilization. Nowadays, almost everyone owns a smart phone, a laptop, or a tablet, and we can watch programs with a big-sized television. Various types of monitors can be seen everywhere, but the production of luminous element has increased the burden on our environment. Moreover, the materials of highly efficient luminous element contain rare-earth or heavy metal elements, causing damage to human health. Therefore, the present thesis aims at adopting materials that contain no rare-earth or heavy metal elements and producing highly efficient fluorescent thin films. These films not only can reduce the cost of production of luminous element but also solve the problems of mass transfer yield and the transfer rate. Our goal is to produce highly efficient red microarray. In this first phase of our experiment, we chose one suitable fluorescent doping - DCJTB from multiple red organic fluorescent dyes to be our sample. Different solvents were mixed with DCJTB and PVP to produce fluorescent solution. By using integrating sphere, the blue LED was emitted to measure excitation spectrum and calculate quantum yield. In order to produce flat thin films, we adjusted spin coating parameter and measured its quantum efficiency rate and absorption rate. In the study, the best quantum efficiency of the thin film is 85% made by the PVP-based process. When using PVP as our host material to produce the thin film, we found that high molecular polymer material was hydrophilic, which might cause difficulties in future production of the array. Therefore, PVB material was adopted to replace PVP. We also tried to use the UV packaged technique to test PVP fluorescent thin film under 1 atm, and compared its outcome to unpackaged technique. During the second phase of our experiment, we used PVB as the host to produce thin film. Likewise, the suitable solvent was mixed with DCJTB and PVB and measured its excitation spectrum and calculated quantum yield. In the study, the spin coating parameter was also adjusted and to measure its quantum efficiency rate and absorption rate, so the best quantum efficiency of the thin film calculated by equation is 89% and the best absorption is 41% made by the PVB-based process. During the production of array, we tried to adjust photolithography parameter and RIE parameter in order to get a complete cuboid, which was consistent with the mask size that we used. The mask size of 60μm20μm及6μm2μm were used. In the future, we would like to demonstrate RGB colors on one piece of substrate. Blue LED will be the base to emit green and red fluorescent array. The luminance of the blue LED will be controlled to generate different colors so that we can produce full color micro pixel.	en
dc.description.provenance	Made available in DSpace on 2021-07-11T15:25:44Z (GMT). No. of bitstreams: 1 U0001-1808202021125500.pdf: 5207096 bytes, checksum: 3b4bb50dbc88cc70733298d1cf04f683 (MD5) Previous issue date: 2020	en
dc.description.tableofcontents	誌謝 I 摘要 II ABSTRACT IV 目錄 VI 圖目錄 IX 表目錄 X 第一章緒論 1 1.1 研究背景 1 1.1.1 照明光源發展史 1 1.1.2 螢光材料介紹 4 1.1.3 稀土材料之隱憂 8 1.2 研究動機 10 1.3 論文大綱 10 第二章理論基礎與文獻回顧 12 2.1 光致發光與電致發光 12 2.2 螢光與磷光 13 2.3 主體與客體能量傳遞 (HOST-GUEST ENERGY TRANSFER) 15 2.4 有激發光染料之發光原理 17 2.5 濃度淬熄效應(CONCENTRATION QUENCHING) 18 2.6 量子效率(QUANTUM YIELD) 19 第三章研究儀器與設備介紹 21 3.1 超音波清淨機(LEO-400S) 21 3.2 電子束蒸鍍系統 22 3.3 黃光微影系統 22 3.4 反應式離子蝕刻系統 23 3.5 光譜分析儀 25 3.6 積分球及光譜分析儀系統 25 3.7 FT-IR光譜儀 26 第四章有機螢光溶液製作與量測(PVP) 28 4.1 實驗動機 28 4.2 實驗架構 29 4.2.1 有機螢光染料與溶劑之選用 29 4.2.2 聚乙烯吡咯烷酮 (Polyvinylpyrrolidone，PVP) 材料簡介 29 4.2.3 溶液與薄膜的製作流程 31 4.2.4 量測與分析 33 4.3 紅色有機螢光染料 34 4.4 有機螢光薄膜的量子效率(QUANTAN YIELD)量測 36 4.5 螢光薄膜的封裝探討 38 4.6 結論 44 第五章有機螢光溶液製作與量測(PVB) 45 5.1 實驗動機 45 5.2 實驗架構 46 5.2.1 DCJTB紅色螢光染料介紹 46 5.2.2 聚乙烯醇縮丁醛(PVB)材料介紹 47 5.2.3 溶液及薄膜製作流程 49 5.2.4 量測與分析 50 5.3 螢光溶液製成薄膜之參數探討 52 5.3.1 螢光溶液之最佳溶劑選擇 52 5.3.2 螢光溶液之PVB摻雜克數 54 5.4 螢光薄膜量子效率量測 55 5.5 不同薄膜厚度之吸收率 58 5.6 薄膜的發光機制 62 5.7 結論 66 第六章紅色螢光微米陣列製作 67 6.1 實驗動機 67 6.2 微米螢光陣列製程 67 6.3 紅色螢光陣列 70 6.3.1 60 μm 20 μm陣列 72 6.3.2 6 μm 2 μm陣列 75 6.4 結論 77 第七章結論與未來展望 78 7.1 結論 78 7.2 未來與展望 80 參考文獻 81
dc.language.iso	zh-TW
dc.subject	有機紅色螢光染料	zh_TW
dc.subject	微米級陣列	zh_TW
dc.subject	有機螢光薄膜	zh_TW
dc.subject	無稀土元素	zh_TW
dc.subject	Organic fluorescent thin film	en
dc.subject	Rare-earth-free element	en
dc.subject	Red organic fluorescent dye	en
dc.subject	Microarray	en
dc.title	製成不同像素尺寸的紅色無稀土螢光材料薄膜之研究	zh_TW
dc.title	Research on Red Rare-Earth-Free Fluorescent Material Film with Different Pixel Size	en
dc.type	Thesis
dc.date.schoolyear	108-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	黃建璋(Jian-Jang Huang),黃定洧(Ding-Wei Huang),葉志庭(Zhi-Ting Ye)
dc.subject.keyword	無稀土元素,有機紅色螢光染料,有機螢光薄膜,微米級陣列,	zh_TW
dc.subject.keyword	Rare-earth-free element,Red organic fluorescent dye,Organic fluorescent thin film,Microarray,	en
dc.relation.page	84
dc.identifier.doi	10.6342/NTU202004030
dc.rights.note	有償授權
dc.date.accepted	2020-08-19
dc.contributor.author-college	電機資訊學院	zh_TW
dc.contributor.author-dept	光電工程學研究所	zh_TW
dc.date.embargo-lift	2025-08-18	-
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