高折射率及高穿透度之二氧化鈦－環氧樹脂奈米複合材料之合成與物性研究

Hsien-Wen Liu; 劉獻文

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/40732

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	林唯芳
dc.contributor.author	Hsien-Wen Liu	en
dc.contributor.author	劉獻文	zh_TW
dc.date.accessioned	2021-06-14T16:57:53Z	-
dc.date.available	2010-08-05
dc.date.copyright	2008-08-05
dc.date.issued	2008
dc.date.submitted	2008-07-30
dc.identifier.citation	1. Adabbo, H.E.; Williams, R. J. J, “The Evolution of Thermosetting Polymers in a Conversion-Temperature Phase Diagram”, J. Appl. Polym. Sci., 27, 1327(1982) 2. Bamwenda, G.R.; Tsubota, S.; Nakamura, T.; Haruta, M., “Photoassisted hydrogen production from a waterethanol solution: a comparison of activities of Au-TiO2 and Pt-TiO2”, J. Photochem. Photobiol. A: Chem.,89,177(1995) 3. Bardos, E. S.; Czili, H.; Horvath, A.,” Photocatalytic oxidation of oxalic acid enhanced by silver deposition on a TiO2 surface”, J. Photochem. Photobiol A: Chem., 154, 195(2003) 4. Bhatanagar, M. S., “Epoxy resin from 1980 to date. Part 1”, Polym.-Plast, Technol. Eng., 32, 53(1993) 5. Boquillon, N.; Fringant, C., “Polymer networks derived from curing of epoxidised linseed oil: influence of different catalysts and anhydride hardeners ”, Polymer, 41, 8603–8613(2000) 6. Bischoff, B. L.; Anderson, M. A., “Peptization Process in the Sol-Gel Preparation of Porous Anatase (TiO2)”, Chem. Mater., 7, 1772 (1995) 7. Brinker, C. J.; Scherer, G.W.; “Sol-gel science“, Academic Press, Inc., San Diego, 1990 8. Birnie III, D. P; Bendzko, N. J., ” 1H and 13C NMR observation of the reaction of acetic acid with titanium isopropoxide”, Materials Chemistry and Physics, 59, 26 (1999) 9. Chen, W. C.; Lee, D. J.; Lee,L. H.; Lin, J. L., “Synthesis and Characterization of Trialkoxysilane-capped Poly(methyl methacrylate)-Titania Hybrid Optical Thin Films”, J. Mater. Chem., 9, 2999 (1999) 10. Chen, W.C.; Liu, W.C.; Wu, P. T.; Chen, P.F.,” Synthesis and characterization of oligomeric phenylsilsesquioxane-titania hybrid optical thin films”, Materials Chemistry and Physics, 83, 71(2004) 11. Cogan, S. F.; Nguyen N. M.; Perrotti S. J.; Rauh R. D.; “Optical properties of electrochromic vanadium pentoxide“, J. Appl. Phys. 66, 3 (1989) 12. Convertino, A.; Leo, G.; Tamborra , C.; Sciancalepore, C.; Striccoli , M.; Curri , M. L.;Agostiano A.,” TiO2 colloidal nanocrystals functionalization of PMMA: A tailoring of optical properties and chemical adsorption”, Sensors and Actuators B, 126 138(2007) 13. Cozzoli, P. D.; Kornowski, A. ; Weller, H., “Low-Temperature Synthesis of Soluble and Processable Organic-Capped Anatase TiO2 Nanorods”, J. Am. Chem. Soc., 125, 14539 (2003). 14. Cuthrell, R. E., “Macrostructure and Enviroment-Influenced Surface Layer in Epoxy Polymers”, J. Appl. Polym. Sci., 11, 949(1967) 15. Davis, R. M. ; Nagpal, V. J.; Desu, S. B., “Novel thin film of titanium dioxide particles synthesized by a sol-gel process”, J. Mater. Res., 10, 12, 3068(1995) 16. Doeuff, S. ; Henry, M.; Sanchez, C.; Livage, J., “Hydrolysis of titanium alkoxides: Modification of the molecular precursor by acetic acid”, J. Non-Cryst. Solids, 89, 206 (1987) 17. Ellis, B., Chemistry and Technology of Epoxy Resins, Blackie Academic and Professional, 1993 18. Guan, C.; Lu, C. L.; Liu, Y. F.; Yang, B.,” Preparation and Characterization of High Refractive Index Thin Films of TiO2/Epoxy Resin Nanocomposites”, Journal of Applied Polymer Science, 102, 1631 (2006) 19. Kominami, H.; Muratami, S.; Kato, J.; Kera, Y.; Ohtani, B., “Correlation between Some Physical Properties of Titanium Dioxide Particles and Their Photocatalytic Activity for Some Probe Reactions in Aqueous Systems”J. Phys. Chem. B, 106, 10501 (2002) 20. Krishnamoorti, R.; Vaia, R. A.; Giannelis,E. P., “Structure and Dynamics of Polymer-Layered Silicate Nanocomposites”, Chem. Mater., 8, 1728 (1996) 21. Krishnamoorti, R.; Vaia, R. A., ”Polymer Nanocomposites Synthesis, Characterization, and Modeling”, American Chemical Society Symposium Series, Washington, DC (2002) 22. Li, Y.; Sui, M.; Ding, Y.; Zhang, G.; Zhuang, J.; Wang, C.,“ Preparation of Mg(OH)2 Nanorods“, Adv. Mater., 12, 818 (2000) 23. Lide, D. R.; “Handbook of Chemistry and Physics”, 71st ed., 4, CRC Press. (1991) 24. Lin, J.; Lin, Y.; Liu, P., Meziani, J. M.,Allard, L. F., Sun, Y. P. , “Hot-Fluid Annealing for Crystalline Titanium Dioxide Nanoparticles in Stable Suspension”, J. Am. Chem. Soc., 124, 11514 (2002) 25. Lu, C.; Cui, Z.; Guan, C.; Guan, J. ;Yang, B.; Shen, J.,” Research on Preparation, Structure and Properties of TiO2/Polythiourethane Hybrid Optical Films with High Refractive Index”, Macromol. Mater. Eng. 2003, 288, 9 (2003) 26. Lu, C.; Cui, Z.; Wang, Y.; Li, Z.; Yang, B.; Shen, J., ” Preparation and characterization of ZnS–polymer nanocomposite films with high refractive index”, J. Mater. Chem., 13, 2189(2003) 27. Lu, C.; Cui, Z.; Li, Z.; Yang, B.; Shen, J.,” High refractive index thin films of ZnS/polythiourethane nanocomposites”, J. Mater. Chem., 13, 526(2003) 28. Lu, C.; Guan, C.; Liu, Y.; Yang, B.,” PbS/Polymer Nanocomposite Optical Materials with High Refractive Index”, Chem. Mater., 17, 2448(2005) 29. Mijovic, J.; Fishbain, A.; Wijayat, J., “Mechanistic modeling of epoxy-amine kinetics. 2. Comparison of kinetics in thermal and microwave fields”, Macromolecules, 25, 986(1992) 30. Misra, T. K.; Liu, C. Y., “Synthesis, isolation, and redispersion of resorcinarene-capped anatase TiO2 nanoparticles in nonaqueous solvents”, Journal of Colloid and Interface Science, 310, 178 (2007) 31. Nakayama, N.; Hayashi, T., ” Preparation and characterization of TiO2–ZrO2 and thiol-acrylate resin nanocomposites with high refractive index via UV-induced crosslinking polymerization”, Composites: Part A, 38, 1996(2007) 32. Nakayama, N.; Hayashi, T., “Preparation and Characterization of TiO2 and Polymer Nanocomposite Films with High Refractive Index”, Journal of Applied Polymer Science, 105, 3662 (2007) 33. Narula, A. K., Ritu Jain, Veena Chaudhary, “Curing and Thermal Behavior of DGEBA in Presence of Dianhydrides and Aromatic Diamine”, J. Appl. Polym. Sci., 105, 3804(2007) 34. Ni, M.; Leung, M. K. H.; Leung, D. Y. C.; Sumathy, K.,” A review and recent developments in photocatalytic water-splitting using TiO2 for hydrogen production”, Renewable and Sustainable Energy Reviews,11 , 401 (2007) 35. Niederberger, M.; Bartl, M. H.; Stucky, G.,“ Benzyl Alcohol and Titanium TetrachloridesA Versatile Reaction System for the Nonaqueous and Low-Temperature Preparation of Crystalline and Luminescent Titania Nanoparticles“, Chem. Mater., 14, 4364 (2002) 36. O’ Regan, B.; Gratzel, M., “A low-cost, high-efficiency solar cell based on dye-sensitized colloidal TiO2 films”, Nature, 353, 737 (1991) 37. Prasad, E .J.; Yoshida. M., ”Sol-gel-processed SiO2/TiO2/Poly(vinylpyrrolidone) Composite Materials for Optical Waveguides”, Chem. Mater.,8,235(1996) 38. Ramakrishna, G.; Ghosh, H. N.,” Optical and Photochemical Properties of Sodium Dodecylbenzenesulfonate (DBS)-Capped TiO2 Nanoparticles Dispersed in Nonaqueous Solvents”, Langmuir, 19, 505 (2003) 39. Rogers, H. G.; Gaudiana, R. A.; Hollinsed, W.C.; Kalyanaraman, P. S.; Manello, J. S.; McGowan C.; Minns, R. A.; Sahatjian, R., “Highly Amorphous, Birefringent, Para-Linked Aromatic Polyamides”, Macromolecules, 18, 1058 (1985) 40. Sanchez, C.; Livage, J.; Henry, M.; Babonneau, F., “Chemical modification of alkoxide precursors”, J. Non-Cryst. Solids, 100, 65, (1988) 41. Sanchez, C.; Livage, J.,” Sol-gel chemistry from metal alkoxide precursor”, New J. Chem., 14, 513 (1990) 42. Shechter, L.; Wynstra, J.; Kurkjy, R. P., 1956, Indu. Engi. Chem., 94 43. Su, H. W.; Chen, W. C., ” High refractive index polyimide–nanocrystalline-titania hybrid optical materials”, J. Mater. Chem., 18, 1139(2008) 44. Su, W.F.; Yuan, H. K.,” High-refractive-index organic-inorganic hybrid materials prepared from polymerizable titanium/bismuth methacryl ethoxide”, ACS Polymer Preprints, 41, 1, 575(2000) 45. Tobolsky, A.V.,” Properties and structure of polymers. New York:Wiley”, 1960 (chap. 1, p. 1–36). 46. Verevkina, O. B.; Kulkova, N. V.; Politova, E. D.; Shevchuk, Y. A.,” Preparation of Thermostable Highly Dispersed Titanium Dioxide from Stable Hydrosols”, Colloid, 65, 226 (2003) 47. Wang, B.; Wilkes, G.L.; Hedrick, J.C.; Liptak, S.C.; Mcgrath, J.E.,” New High Refractive Index Organic/Inorganic Hybrid Materials from Sol-Gel Processing”, Macromolecules,24, 3449(1991) 48. Wang, B.Q.; Jing, L.Q.; Qu, Y.C. et al., “Enhancement of the photocatalytic activity of TiO2 nanoparticles by surface-capping DBS groups”, Applied Surface Science, 252, 8, 2817 (2006) 49. Williams, R. J. J.; Riccardi, C. C., “A Kinetic Scheme for an Amine-Epoxy Reaction with Simultaneous Etherification”, J. Appl. Polym. Sci., 32, 3445(1986) 50. Wu, N.L; Lee, M.S.,” Enhanced TiO2 photocatalysis by Cu in hydrogen production from aqueous methanol solution”, J. Photochem. Photobiol. A: Chem., 29, 15, 1601(2004). 51. Yoldas, B. E., “ Hydrolysis of titanium alkoxide and effects of hydrolytic polycondensation parameters“, J. Mater. Sci., 21, 1087 (1986) 52. Yoshida, M., ” TiO2 nano-particle-dispersed polyimide composite optical waveguide materials through reverse micelles”, J. of Material Science,32,4047(1997) 53. Zhao, J.; Lai, Z., “Absorption red shift in TiOs ultrafine particles with surfacial dipole layer”, Applied physics letters, 59, 1826 (1991) 54. Zhu, Y.; Shi, J.; Zhang, Z.; Zhang, C.; Zhang, X., “Development of a Gas Sensor Utilizing Chemiluminescence on Nanosized Titanium Dioxide”, Anal. Chem , 74, 120 (2002) 55. 傅雅卿，”高折射率環氧樹脂之合成及其物性研究”，台灣大學材料科學與工程學研究所碩士論文，2001 56. 張佐光，”功能複合材料”，曉園出版社，2006 57. 張國馨，'以表面改質及分散技術製備高折射率有機－無機奈米複合材料'，台灣大學材料科學與工程學研究所碩士論文，2006 58. 黃建睿，'液晶型環氧樹脂硬化反應動力學與性質研究'，台灣大學高分子科學與工程學研究所碩士論文，2007
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/40732	-
dc.description.abstract	隨著科技的進步，發展出利用高折射率奈米粒子與高分子混摻製備有機－無機奈米複合材料之技術，此奈米複合材料除了擁有高折射率及高透明度外，更有著低熱膨脹係數、良好的熱穩定性、優秀的機械性能等，因此可作為封裝材料、光波導及光學鏡片等材料。本研究成功以溶膠凝膠法製備粒徑低於30nm之結晶性二氧化鈦奈米粒子，並使用界面活性劑進行表面改質，使二氧化鈦能夠均勻地分散至有機溶劑中。我們討論不同改質劑對二氧化鈦在溶液狀態下的光學性質影響。接著將表面改質的二氧化鈦與環氧樹脂摻混後製成高折射率、高穿透度的奈米複合材料。動態反應動力學的研究方面，藉由熱差微分分析儀(DSC)測量複合材料的”熱流對溫度”曲線及利用Kissinger model的理論計算，我們得知硬化反應之活化能(Ea)、反應放熱峰最大值所對應的溫度(Tp)及反應放熱量(∆H)皆隨改質二氧化鈦含量增加而下降。光學性質研究方面，硬化後的複合材料折射率隨著二氧化鈦固含量的增加而線性上升，雖然環氧樹脂本身的折射率低，但是加入折射率高的改質二氧化鈦含量至40wt%時，奈米複合材料在波長為633nm下的折射率可由1.54提升至1.73。另外，由於改質後的二氧化鈦能均勻的分散在高分子基質中，藉由紫外光-可見光圖譜分析儀(UV-Vis spectrum)得知材料在波長範圍500-800nm時，穿透度仍達90%以上。硬化後的奈米複合材料分別利用熱差掃描計(DSC)、熱機械分析儀(TMA)、熱重分析儀(TGA)、以及微硬度測試來分析其熱性質與機械性質。隨著改質後二氧化鈦含量的增加，材料的玻璃轉移溫度（Tg）下降且耐熱性變差；但加熱到更高溫度時，由於導入了無機粒子二氧化鈦，故殘重隨二氧化鈦含量增加而上升。	zh_TW
dc.description.abstract	Along with the evolution of technology, the fabrication of the organic-inorganic nano composite was developed by blending the nano-sized particles and the polymers. Nanocomposites had many advantages such as high refractive index, low thermal expansion coefficient, good thermal stability, and excellent mechanical properties. The high refractive index materials can be widely used as encapsulants , optical waveguides and optical lenses, etc. In this research, crystalline TiO2 nanoparticles with an average size smaller than 30nm were successfully synthesized via sol-gel process. After surface modification, the TiO2 nanoparticles were stabilized and well dispersed in organic solvents to form transparent TiO2 nanoparticle colloidal solutions. Through the UV-vis spectra, we studied how the surfactants influenced the optical properties of surface modified TiO2 in solution state. Then, the surface modified TiO2 nanoparticle solutions were mixed with epoxy resin to fabricate organic-inorganic hybrid materials with high refractive index and high transparency. Differential scanning calorimetry(DSC) was used to investigate the cure kinetics of the composite. We found that the activation energy (Ea) determined in accordance to Kissinger’s method, the peak temperature of exotherm (Tp), and the heat of curing(∆H) decreased with increasing concentration of surface modified TiO2. The refractive index of cured nanocomposite films was in the range of 1.54–1.73 at 633nm, which linearly increased with the content of TiO2 nanoparticles from 0 to 40 wt %. The transmittance of the cured nanocomposite was higher than 90% because the well dispersion of surface modied TiO2 in the polymer matrix, which avoid the effect of light scattering caused by particle aggregation. Differential scanning calorimetry (DSC), thermomechanical analysis (TMA), thermogravimetric analysis (TGA) and microhardness tests were applied to characterize the cured nanocomposite materials.	en
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dc.description.tableofcontents	目錄摘要.....................................................I Abstract................................................II 目錄....................................................IV 圖目錄................................................VIII 表目錄..................................................XI 第一章緒論...............................................1 1.1 前言.................................................1 1.2 研究目的與動機.......................................1 1.3 研究方向.............................................2 第二章文獻回顧..........................................3 2.1 溶膠凝膠法...........................................3 2.1.1 以溶膠凝膠法製備二氧化鈦奈米粒子...................4 2.1.2 影響鈦烷氧化物進行溶膠凝膠法反應之因子.............5 2.1.3 鈦烷氧化物之表面改質...............................6 2.2 二氧化鈦奈米粒子之表面改質...........................7 2.2.1 二氧化鈦奈米粒子的無機改質.........................8 2.2.2 無機改質應用在增進可見光下二氧化鈦催化性質.........8 2.2.3 二氧化鈦奈米粒子的有機改質........................10 2.2.4 影響二氧化鈦奈米粒子有機改質的主要因素............10 2.2.5 二氧化鈦表面改質後的光學性質變化..................12 2.3 環氧樹脂............................................16 2.3.1 環氧樹脂之硬化....................................16 2.3.2 環氧樹脂硬化過程與硬化劑之使用....................17 2.3.3 硬化反應與溫度的關係..............................17 2.3.4 環氧樹脂與胺類硬化劑之硬化反應機構................18 2.3.5 環氧樹脂與酸酐類硬化劑............................20 2.3.5.1 加入反應促進劑之硬化反應機構....................20 2.3.5.2 添加促進劑對材料性質之影響......................21 2.4 高分子複合材料......................................25 2.4.1 高折射率高分子複合材料............................26 2.4.2 高折射率高分子複合材料的發展......................27 第三章實驗.............................................28 3.1 實驗藥品............................................28 3.1.1 環氧樹脂..........................................28 3.1.2 其他藥品..........................................29 3.2 實驗儀器............................................30 3.3 實驗步驟............................................32 3.3.1 二氧化鈦之表面有機改質............................32 3.3.1.1 以DBS表面改質之二氧化鈦合成－TiO2 (Ａ)..........32 3.3.1.2 以正己胺置換DBS改質之二氧化鈦合成－TiO2 (B).....32 3.3.1.3 以醋酸表面改質之二氧化鈦合成－TiO2 (HOAc).......33 3.3.1.4 以正己胺置換醋酸改質之二氧化鈦合成－TiO2 (C)....33 3.3.1.5 以,1,6,6-四甲基-1,6-己二胺置換醋酸改質之二氧化鈦合成－TiO2 (D)..........................34 3.3.2 環氧樹脂摻混改質二氧化鈦之奈米複合材料............35 3.3.2.1 實驗流程圖......................................35 3.3.2.2 樣品之製備......................................35 3.4 實驗測試項目與樣品製備方法..........................36 3.4.1 硬化前樣品之動力學分析............................36 3.4.2 硬化後樣品之光學性質分析..........................36 3.4.3 硬化後樣品之熱性質分析............................36 3.4.4 硬化後樣品之機械性質分析..........................37 第四章結果與討論......................................38 4.1 二氧化鈦表面改質後之鑑定分析........................38 4.1.1 以DBS改質之二氧化鈦鑑定分析－TiO2 (A).............39 4.1.2 以正己胺置換DBS改質之二氧化鈦鑑定分析－TiO2 (B)...41 4.1.3 以醋酸改質之二氧化鈦鑑定分析－TiO2 (HOAc).........44 4.1.4 以正己胺置換HOAc改質之二氧化鈦鑑定分析－TiO2 (C)..47 4.1.5 以1,1,6,6-四甲基-1,6-己二胺置換HOAc改質之二氧化鈦鑑定分析－TiO2 (D)........................49 4.2 折射率比較..........................................52 4.2.1 不同環氧樹脂之折射率比較..........................52 4.2.2 不同改質劑之二氧化鈦折射率比較....................53 4.3 以胺類置換醋酸前與置換後之性質比較..................54 4.3.1 置換前後之吸收光譜比較............................54 4.3.2 置換前後之光穿透度比較............................55 4.3.3 置換前後對於複合材料薄膜平整度的影響..............56 4.4 DM-TiO2-(C)-X系統之奈米複合材料性質分析.............58 4.4.1 DM-TiO2-(C)-X系統之動力學分析.....................58 4.4.2 DM-TiO2-(C)-X系統之熱性質分析.....................61 4.4.2.1 DM-TiO2-(C)-X系統之熱重分析....................61 4.4.2.2 DM-TiO2-(C)-X系統之玻璃轉移溫度分析............63 4.4.2.3 DM-TiO2-(C)-X系統之TMA分析.....................66 4.4.3 DM-TiO2-(C)-X系統之機械性質分析...................67 4.4.4 DM-TiO2-(C)-X系統之折射率分析.....................68 4.4.5 DM-TiO2-(C)-X系統之光穿透度分析...................69 4.5 DM-TiO2-(D)系統之奈米複合材料性質分析...............71 4.5.1 DM-TiO2-(D)-X系統之動力學分析.....................71 4.5.2 DM-TiO2-(D)-X系統之熱性質分析.....................73 4.5.2.1 DM-TiO2-(D)-X系統之熱重分析....................73 4.5.2.2 DM-TiO2-(D)-X系統之玻璃轉移溫度分析............75 4.5.2.3 DM-TiO2-(D)-X系統之TMA分析.....................78 4.5.3 DM-TiO2-(D)系統之機械性質分析.....................79 4.5.4 DM-TiO2-(D)系統之折射率分析.......................80 4.5.5 DM-TiO2-(D)系統之光穿透度分析.....................81 第五章結論............................................82 第六章建議............................................83 參考文獻................................................84 圖目錄 Figure 2.1 Molecular structure of Ti(OR)4 precursors.......5 Figure 2.2 Mechanism of TiO2 photocatalytic water-splitting for hydrogen production.........9 Figure 2.3 The effects of the pH value on the charge states of TiO2 surfaces and the existing form of DBS groups..................................11 Figure 2.4 Excitation (curve c) and emission (curve d) spectra of DBS-capped TiO2 nanoparticles in DMF.........................................12 Figure 2.5 UV–vis spectra of (a) C11-resorcinarene, (b)C11-resorcinarene-capped TiO2 NPs in 1-propanol, and (c) C11-resorcinarene-capped TiO2 NPs in dichloromethane....................13 Figure 2.6 One possibility of the mechanism of yellow coloring.......................................14 Figure 2.7 Conversion-temperature phase diagram of thermosetting polymer..........................18 Figure 3.1 Flow diagram of Epoxy resin-TiO2-(X) nanocomposite..................................35 Figure 4.1 Size distribution of TiO2 (A) colloid solution ...............................................39 Figure 4.2 XRD pattern of TiO2 (A)........................40 Figure 4.3 TEM photo of TiO2 (A)..........................40 Figure 4.4 FT-IR spectra of DBS and TiO2 (A)..............41 Figure 4.5 Size distribution of TiO2 (B) colloid solution ...............................................41 Figure 4.6 XRD pattern of TiO2 (B)........................42 Figure 4.7 TEM photo of TiO2 (B)..........................42 Figure 4.8 FT-IR spectra of TiO2 (A), TiO2 (B), and hexylamine.....................................43 Figure 4.9 Size distribution of TiO2 (HOAc)...............44 Figure 4.10 XRD pattern of TiO2 (HOAc)....................45 Figure 4.11 TEM photo of TiO2 (HOAc)......................45 Figure 4.12 FT-IR spectra of HOAC and TiO2 (HOAc).........46 Figure 4.13 XRD pattern of TiO2(C)........................47 Figure 4.14 TEM photo of DM-TiO2(C)-5.....................48 Figure 4.15 FT-IR spectra of TiO2 (HOAc), TiO2 (C), and hexylamine....................................49 Figure 4.16 XRD pattern of TiO2 (D).......................49 Figure 4.17 TEM photo of DM-TiO2 (D)-5....................50 Figure 4.18 FT-IR spectrum of N,N,N',N'-Tetramethyl-1,6- hexanediamine.................................51 Figure 4.19 FT-IR spectrum of TiO2 (D)....................51 Figure 4.20 Refractive index of cured DD-TiO2-X series at 633nm......................................53 Figure 4.21 Optical absorption spectra of surface modified TiO2 in solution state...............55 Figure 4.22 Optical transmittance spectra of the cured DM-TiO2-5.....................................56 Figure 4.23 AFM images of cured composites with different surface modified TiO2.........................57 Figure 4.24 Optical microscopy observation of cured composites with different surface modified TiO2..........................................57 Figure 4.25 Heat flow versus temperature for DM-TiO2(C)-(X) system：(a)X=0 (b)X=5 (c)X=10.................59 Figure 4.26 Kissinger’s model for DM-TiO2(C)-(X) system： (a)X=0 (b)X=5 (c)X=10.........................60 Figure 4.27 TGA curves of Cured DM-TiO2(C)-X series.......62 Figure 4.28 DSC curves of cured DM-TiO2(C)-X series.......63 Figure 4.29 TMA curves of cured DM-TiO2(C)-X series.......64 Figure 4.30 DSC curves of cured (DM+hexylamine) series....65 Figure 4.31 DSC curves of cured (DM+Acetic acid) series...65 Figure 4.32 Tg vs. surfactant added for DM system.........66 Figure 4.33 Microhardness measurements of DM-TiO2-(C)-X...67 Figure 4.34 Refractive index of cured DM-TiO2(C)-X system at 633nm...............................69 Figure 4.35 The transmittance spectra of cured DM-TiO2(C)-X system...........................70 Figure 4.36 Heat flow versus temperature for DM-TiO2(D)-(X) system：(a)X=0 (b)X=5 (c)X=10.................71 Figure 4.37 Kissinger’s model for DM-TiO2(D)-(X) system： (a)X=0 (b)X=5 (c)X=10.........................72 Figure 4.38 TGA curves of cured DM-TiO2(D)-X series.......74 Figure 4.39 DSC curves of cured DM-TiO2(D)-X series.......75 Figure 4.40 TMA curves of cured DM-TiO2(D)-X series.......76 Figure 4.41 DSC curves of cured (DM+ N,N,N',N'- tetramethylhexane-1,6-diamine) Series.........77 Figure 4.42 DSC curves of cured (DM+Acetic acid) series...77 Figure 4.43 Tg vs surfactant added for DM system..........78 Figure 4.44 Microhardness measurements of DM-TiO2-(D)-X...79 Figure 4.45 Refractive index of cured DM-TiO2(D)-X system at 633nm...............................80 Figure 4.46 The transmittance spectra of cured DM-TiO2 (D)-X system..........................81 表目錄 Table 2.1 The Dispercive Property of TiO2 Modified by Propionic Acid and a Variety of Alkyl Amines....14 Table 2.2 Color Change of Colloid Solution When Adding a Small Amount of Bisphenol-A or Anisole..........15 Table 2.3 Formulas of catalysts used......................21 Table 2.4 DSC results on catalyst type and concentration influence on ELO–THPA systems..................22 Table 2.5 Molecular weight between crosslinks (Mc) for networks prepared by curing ELO with THPA (R= 0.8) and different amounts of 2MI...........23 Table 2.6 Results of DSC scans of DGEBA in presence of DDS/BTDA mixture................................24 Table 2.7 Results of DSC scans of DGEBA in presence of DDS/NTDA mixture................................24 Table 2.8 Results of TG/DTG Traces of Cured Epoxy Resins in Nitrogen Atmosphere..........................25 Table 2.9 Results of TG/DTG Traces of Cured Epoxy Resins in Nitrogen Atmosphere..........................25 Table 2.10 Comparisons of optical materials...............26 Table 2.11 Referential Literatures of High Refractive Index Composites...............................27 Table 4.1 Characterization of surface modified TiO2.......38 Table 4.2 Refractive index comparisions of various epoxy resin systems...................................53 Table 4.3 DSC results on TiO2 content influence for DM-TiO2(C)-X system.............................60 Table 4.4 TGA results on TiO2 content influence on cured DM-TiO2(C)-X system.............................62 Table 4.5 Tg comparison of cured DM-TiO2(C)-X series (DSC and TMA)...................................64 Table 4.6 Thermal expansion coefficients and Tg of cured DM-TiO2(C)-X series.............................66 Table 4.7 Microhardness of cured DM-TiO2-(C)-X system.....67 Table 4.8 DSC results on TiO2 content influence for DM-TiO2 (D)-X system............................73 Table 4.9 TGA results on TiO2 content influence on cured DM-TiO2 (D)-X system............................74 Table 4.10 Tg comparison of Cured DM-TiO2(D)-X series (DSC and TMA)..................................76 Table 4.11 Thermal expansion coefficients and Tg of cured DM-TiO2 (D)-X series...........................78 Table 4.12 Microhardness of cured DM-TiO2-(D)-X system....79
dc.language.iso	zh-TW
dc.subject	二氧化鈦	zh_TW
dc.subject	折射率	zh_TW
dc.subject	奈米複合材料	zh_TW
dc.subject	溶膠-凝膠法	zh_TW
dc.subject	催化劑	zh_TW
dc.subject	環氧樹脂	zh_TW
dc.subject	nanocomposite	en
dc.subject	titanium dioxide	en
dc.subject	epoxy resin	en
dc.subject	catalyst	en
dc.subject	sol-gel	en
dc.subject	refractive index	en
dc.title	高折射率及高穿透度之二氧化鈦－環氧樹脂奈米複合材料之合成與物性研究	zh_TW
dc.title	Synthesis and Physical Properties of TiO2-Epoxy Resin Nanocomposite with High Refractive Index and High Transparency	en
dc.type	Thesis
dc.date.schoolyear	96-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	林金福,廖文彬,林有銘
dc.subject.keyword	折射率,奈米複合材料,溶膠-凝膠法,催化劑,環氧樹脂,二氧化鈦,	zh_TW
dc.subject.keyword	refractive index,nanocomposite,sol-gel,catalyst,epoxy resin,titanium dioxide,	en
dc.relation.page	89
dc.rights.note	有償授權
dc.date.accepted	2008-07-30
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	高分子科學與工程學研究所	zh_TW
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