14. Philip p Baker, Ultracapacitors for Use in Power Quality and Distributed Resource Applications ,Power Engineering Society Summer Meeting, , IEEE (2002), p 316-320 vol.1.
15. R.W.Reeve, P.A.Christensen, A.J.Dickinson, A.Hamnett, K. Scott, Methanol-Tolerant Oxygen Reduction Catalysts Based on Transition Metal Sulfides and Their Application to the Study of Methanol Permeation ,Electrochimica Acta 45 (2000), 4237-4250.
16. C.-H. Bae, E.pL. Roberts, R.A.W. Dryfe, Chromium Redox Couples for Application to Redox Batteries ,Elecrtrochimica Acta 48 (2002), 279-287.
17. 陳元杰, 廖秋峰, 超高容量電容及電池混合店員模組之應用 ,工業材料雜誌 178 期(90 年 10 月), p100-p106.
18. 朱宏傳, 吳德海, 徐才祿, 奈米碳管 ,機械工業出版社 (2003).
19. 高志勇, 陳耿陽, 吳富其, 江萬爵, 賴志坤, 超高電容器製程技術簡介 ,工業材料 雜誌166 期 (89 年 10 月), p113~119.
20. NEC Research and Development ,Sanada S., Hasokawa M., 1979, 55, p22-27.
21. 陳慶洪, 柯澤豪, 簡鴻裕, 林世偉, 蘇庭頤, 碳化處理對以 Phenolic 系活性碳纖維 布製程電雙層電容器之影響 ,2002 年材料年會 PE-1。
22. 侯天益, 周惠育, 劉安民, 羅法聖, 翁炳志, 吳宗明, 超高電容研製 ,中山科學研 究院材料暨光電研究所, 2002 年材料年會 PE-8。
23. M. F. Rose and S. A. Merryman, Electrochemical Capacitor Technology for Actuator Applications ,Energy Conversion Engineering Conference, 1996. IECEC 96.
Proceedings of the 31st Intersociety, Volume: 1, 11-16 Aug. 1996 Page(s): 245 -250 vol.1. 1996 IEEE.
24. Stephen M. Lipka, Electrochemical Capacitors Utilizing Low Surface Area Carbon Fiber ,IEEE AES Systems Magazine, July 1997.
in Supercapacitors ,TENCON 2000. Proceedings, Volume: 3, 24-27 Sept. 2000 Page(s): 193 -199 vol.3, IEEE 2000
26. F. Belhachemi, S. Raĕl, B. Davat, A Physical Based Model of Power Electric Double-Layer Supercapacitors ,Industry Applications Conference, 2000.
Conference Record of the 2000 IEEE, Volume: 5, 8-12 Oct. 2000 Page(s): 3069 -3076 vol.5, IEEE 2000.
27. 黃孟娟, 張榮錡, 釕氧化物超高電容材料特性簡介 ,工業材料雜誌 182 期 (91 年 2 月), p120~128.
28. Agata Michalska, Krzysztof Maksymiuk, The Specific Influence of Hydrogen Ions on Poly (Pyrrole) Potentionmetry ,Electrochimical Acta 44 (1999), 2125-2129.
29. Klaus-Michael Mangold, Konrad Morgenschweis, Klaus Jüttner, Relaxation of Polythiophenes Bridged by Alkyl Chains ,Electrochimica Acta 44 (1999), 1865-1869.
30. C.Arbizzani, M. Mastragostino, F.soavi, New Trends in Electrochemical Supercapacitors ,Journal of Power Sources 110 (2001), 164-170.
31. K. Rajendra Prasad, N. Munichandriah, Fabrication and Evaluation of 450 F Electrochemical Redox Supercapacitors Using Inexpensive and High-Performance, Polyaniline Coated, stainless-Steel Electrodes ,Journal of Power Sources 112 (2002), 443-451.
32. Chi-Chang Hu and Xi-Xun Lin, Ideally Capacitive Behavior and X-Ray Photoelectron Spectroscopy Characterization of Polypyrrole, Effects of Polymerization Temperatures and Thickness/Coverage ,Journal of Electrochemical Society 149 (8) (2002), A1049-A1057.
33. 莊博堯, 胡啓章, 電化學製備錳─鈷氧化物於電化學電容器的應用及成長機制研 究 ,國立中正大學化學工程研究所碩士論文 (2004).
34. 張仍奎,蔡文達, 含水氧化錳電極之製備與擬電容特性研究 ,材料年會 (2002), PE-17。
35. 黃厚升, 林育立, 陰極沉積法制備含水釕化物超電容特性及其陽極氧化效應探 討 ,中國機械工程學會 93 年學術研討會, D0100846.
36. 黃厚升, 林育立, 陰極沉積法制備含水釕化物超電容特性及其熱處理效應探 討 ,中國機械工程學會 93 年學術研討會, D0100884.
37. Miller J M, Dunn B, Tran T D, Pekala R W, Deposition of Ruthenium Nanoparticles on Carbon Aergels for High energy Density Supercapacitor electrodes ,Journal of Electrochemical Society, 1997, 144 (12), 309~311.
38. Jim P.Zheng, Ruthenium Oxide-Carbon Composite Electrodes for Electrochemical Capacitors ,Electrochemical and Solid-State Letters, 2 (8) 359-361(1999).
39. V. Horvat-Radošević, K.Kvastek, M.Vuković, D. Čukman, Electrochemical Properties of Ruthenised Electrodes in The Oxide Layer Region ,Journal of Electrochemical Chemistry 482 (2000), 188-201.
40. Jong-in Hong In-Hyeong Yeo and Woon-kie Paik, Conducting Polymer with Metal Oxide for Electrochemical Capacitor Poly (3, 4-ethylenedioxythiophene) RuOx
Electrode ,Journal of Electrochemical Society 148 (2) (2001), A156-A163.
41. Ⅱ-Hwan Kim and Kwang-Bum Kim, Ruthenium Oxide Thin Film Electrodes for Supercapacitors ,Electrochemical and Solid-State Letters, 4 (5) (2001), A62-A64.
42. Xiuling Wang, Anbao Yuan, Yuqin Wang, Supercapacitive behaviors and their temperature dependence of sol–gel synthesized nanostructured manganese dioxide in lithium hydroxide electrolyte ,Journal of Power Sources 172 (2007), 1007–1011.
43. 黃耀煌, 胡啟章, 循環伏安法製備含水釕氧化物於電化學電容器之應用 ,國立中 正大學化學工程研究所87 年碩士論文.
44. 張光揮, 胡啟章, 循環伏安法製備含水釕銥氧化物於電化學電容器之應用 ,國立
中正大學化學工程研究所88 年碩士論文。
45. Chi-Chang Hu, Yao-Huang Huang, Effects of Preparation Variables on the Deposition Rate and Physicochemical Properties of Hydrous Ruthenium Oxide for Electrochemical Capacitors ,Electrochimica Acta 46 (2001), 3431-3444.
46. 王振慶, 胡啟章, 活性碳披覆釕氧化物電極於電化學電容器的應用 材料年會 (2002), PE-5.
47. 李明宗, 張六文, 陳志雄, 林中魁, 氧化釕薄膜衝放電機構之 X 光吸收與光電子 能譜研究 ,材料年會 (2002), PE-17。
48. Jianguo Wen, Zhentao Zhou, Pseudocapacitance characterization of hydrous ruthenium oxide prepared via cyclic voltammetric deposition ,Materials Chemistry and Physics 98 (2006), 442–446.
49. T. U. Jeong and A. Manthiram, Amorphous Ruthenium-Chromium Oxides for Electrochemical Capacitors ,Electrochemical and Solid-State Letters, 3 (5) (2000), 205-208.
50. Manikandan Ramani, Bala S.Haran, Ralph E. White, and Branko N. Popov, Synthesis and Characterization of Hydrous Ruthenium Oxide-Carbon Supercapacitors ,Journal of the Electrochemical Society, 148 (4) (2001), A374-A380.
51. Chi-Chang Hu, Yao-Huang Huang, Kwang-Huei Chang, Annealing Effects on the Physicochemical Characteristics of Hydrous Ruthenium and Ruthenium-Iridium Oxides for Electrochemical Supercapacitors ,Joural of Power Sources 108 (2002) 117-127.
52. Suk-Fun Chin, Suh-Cem Pang, and Marc A. Anderson, Material and Electrochemical Characterization of Tetrapropylammonium Manganese Oxide Thin Films as Novel Electrode Materials for Electrochemical
Capacitors ,Journal of the Electrochemical Society, 149 (4) (2002), A379-A384.
53. Iijima, Sumio, Helical microtubules of graphitic carbon ,Nature 354 (1991), 56–58.
54. ADVANCE NANOPOWER INC , 明 鑫 科 技 公 司 ,http://www.anp.com.tw/main01.htm
55. M.S. Dresselhaus, G. Dresselhaus, R. Saito, Physics of carbon nanotubes ,Carbon, Vol. 33, No. 7 (1995) pp. 883-891.
56. Ebbesen T. W., Ajayan, P. M, Large-scale synthesis of carbon nanotubes ,Nature 358 (1992), 220–222.
57. Yahachi Saito, Sashiro Uemura, Field emission from carbon nanotubes and its application to electron sources ,Carbon 38 (2000) 169–182
58. Guo Ting, Nikolaev Pavel, Rinzler Andrew G., Tomanek David, Colbert Daniel T, Smalley Richard E, Self-Assembly of Tubular Fullerenes ,J. Phys. Chem. 99 (1995) 10694–10697.
59. T. Guo, P. Nikolaev, A. Thess, D.T. Colbert, R.E. Smalley, Catalytic growth of single-walled nanotubes by laser vaporization ,Chem. Phys. Lett. 243 (1995) 49–54.
60. C.Journet, P.Bernier, Appl. Phys. A, 67 (1998) 1 .
61. Polytechnic Of Turin ,http://areeweb.polito.it/ricerca/carbongroup/main.html 62. S. Musso, G. Fanchini, A. Tagliaferro, Growth of vertically aligned carbon
nanotubes by CVD by evaporation of carbon precursors ,Diamond & Related Materials 14 (2005) 784- 789.
63. Samuele Porro, Simone Musso, Mauro Giorcelli and Alberto Tagliaferro, Thermal CVD Growth of Carbon Nanotubes Thick Layers ,Proceeding CIMTEC
Conference 2006 - Advances in Science and Technology 48 (2006) 37-43
64. S. Porro, S. Musso, M. Giorcelli and A. Tagliaferro S. H. Dalal, K. B.K. Teo, D. A.
Jefferson and W. I. Milne, Study of CNTs and nanographite grown by thermal CVD using different precursors ,Proceeding ICANS 2006 - Journal of Non-Crystalline Solids 352 (2006) 1310-1313
65. M. Okai, T. Muneyoshi, T. Yaguchi, and S. Sasaki, Structure of carbon nanotubes grown by microwave-plasma-enhanced chemical vapor deposition ,Applied Physics Letters 77 (2000) 3468.
66. Z. P. Huang, J. W. Xu, Z. F. Ren, and J. H. Wang, M. P. Siegal and P. N. Provencio, Growth of highly oriented carbon nanotubes by plasma-enhanced hot filament chemical vapor deposition ,Applied Physics Letters 73 (1998) number 26.
67. Fumiyuki Hoshi, Kazuo Tsugawa, Akiko Goto, Takefumi Ishikura, Satoshi Yamashita, Motoo Yumura, Takashi Hirao, Kenjiro Oura, Yoshinori Koga, Field emission and structure of aligned carbon nanofibers deposited by ECR-CVD plasma method ,Diamond and Related Materials 10 (2001) 254_259.
68. Jie Wang, Youlong Xu , Xi Chen, Xiaofei Sun. Capacitance properties of single wall carbon nanotube/polypyrrole composite films ,Composites Science and
Technology 67 (2007) 2981–2985.
69. Elzbieta Frackowiak, Franc¸ois Be´guin. Electrochemical storage of energy in carbon nanotubes and nanostructured carbons ,Carbon 40 (2002) 1775–1787.
70. Hyeong Taek Ham, Yeong Suk Choi, Namjo Jeong, In Jae Chung. Singlewall carbon nanotubes covered with polypyrrole nanoparticles bythe miniemulsion polymerization ,Polymer 46 (2005) 6308–6315.
71. Tao Liu, T.V. Sreekumar, Satish Kumar, Robert H. Hauge, Richard E. Smalley.
SWNT/PAN composite film-based supercapacitors
72. Grzegorz Lota, Elzbieta Frackowiak, Jagjiwan Mittal, Marc Monthioux. High performance supercapacitor from chromium oxide-nanotubes based electrodes , Chemical Physics Letters 434 (2007) 73–77.
73. Chongfu Zhou, Tao Liu, Tong Wang, Satish Kumar. PAN/SAN/SWNT ternary composite: Pore size control and electrochemical supercapacitor behavior ,Polymer 47 (2006) 5831-5837.
74. Chunsheng Du, Ning Pan, Supercapacitors using carbon nanotubes films by electrophoretic deposition ,Journal of Power Sources 160 (2006) 1487–1494.
75. Gui-Xin Wang, Bo-Lan Zhang, Zuo-Long Yu, Mei-Zhen Qu, Manganese oxide/MWNTs composite electrodes for supercapacitors ,Solid State Ionics 176 (2005) 1169–1174.
76. Yanzhen Zheng, Milin Zhang, Peng Gao, Preparation and electrochemical properties of multiwalled carbon nanotubes–nickel oxide porous composite for supercapacitors ,Materials Research Bulletin 42 (2007) 1740–1747.
77. E. Frackowiak, K. Jurewicz, K. Szostak,S. Delpeux, F. Be´guin, Nanotubular materials as electrodes for supercapacitors ,Fuel Processing Technology 77–78 (2002) 213– 219.
78. Hongyu Mi, Xiaogang Zhang, Shuying An, Xiangguo Ye, Sudong Yang, Microwave-assisted synthesis and electrochemical capacitance of polyaniline/multi-wall carbon nanotubes composite ,Electrochemistry Communications 9 (2007) 2859–2862.
79. Girish Arabale, Deepali Wagh, Mahesh Kulkarni, I.S. Mulla, S.P. Vernekar, K.Vijayamohanan, A.M. Rao, Enhanced supercapacitance of multiwalled carbon nanotubes functionalized with ruthenium oxide ,Journal of Power Sources 160
(2006) 1487–1494.
80. Xiaorong Liu, Trisha A. Huber, Michael C. Kopac, Peter G. Pickup, Ru oxide/carbon nanotube composites for supercapacitors prepared by spontaneous reduction of Ru(VI) and Ru(VII) ,Electrochimica Acta 54 (2009), 7141–7147.
81. Qiao-Ling Chen, Kuan-Hong Xue, Wei Shen, Fei-Fei Tao, Shou-Yin Yin, Wen Xu, Fabrication and electrochemical properties of carbon nanotube array electrode for supercapacitors ,Electrochimica Acta 49 (2004) 4157–4161.
82. Elzbieta Frackowiaka, Franc¸ois Be´guinb, Electrochemical storage of energy in carbon nanotubes and nanostructured carbons ,Carbon 40 (2002) 1775–1787.
83. Tarik Bordjiba, Mohamed Mohamedi, Le H. Dao, Brahim Aissa, My Ali El Khakani, Enhanced physical and electrochemical properties of nanostructured carbon nanotubes coated microfibrous carbon paper ,Chemical Physics Letters 441 (2007) 88–93.
84. E. Frackowiak, S. Delpeux, K. Jurewicz, K. Szostak,D. Cazorla-Amoros, F. B_eguin, Enhanced capacitance of carbon nanotubes through chemical activation
,Chemical Physics Letters 361 (2002) 35–41.
85. R.Z.Ma et.al., Study of electrochemical capacitors utilizing carbon nanotube electrodes ,Journal of Power Sources 84 (1999) 126-129.
86. J.H.Chen et.al., Electrochemical characterization of carbon nanotubes as electrode in electrochemical double-layer capacitors ,Carbon ( 2002 ) , 1193-1197.
87. Q.Jiang et.al., A study of activated carbon nanotubes as electrochemical super capacitors electrode materials ,Materials Letter 57(2002), 988-991.
88. Ch. Emmenegger et.al., Investigation of electrochemical double-layer(ECDL)
capacitors electrodes based on carbon nanotubes and activated carbon