參考文獻 |
[1] C. J. M Chin, L. C. Shih, H. J. Tsai, and T. K. Liu, “ Adsorption of o-Xylene and p-Xylene from Water by SWCNTs “, Carbon, 45, pp.1254-1260 (2007).
[2] 李元堯,「21世紀的尖端材料–奈米碳管」,化工技術,第11卷第2期,第140–159頁,2003。
[3] 洪昭南、徐逸明、王宏達 ,「奈米碳管結構及特性簡介」,化工,第49卷第1期,第23–30頁,2002。
[4] S Iijima, “ Helical Microtubules of Graphitic Carbon,” Nature, 354, pp.56 (1991).
[5] 化工產業技術知識網: http://www.chemtech.com.tw
[6] 麥富德,「碳奈米管專利地圖及分析carbon nanotube eng 麥富德等作」,行政院國科會科資中心,台北,2002。
[7] 黃建良、黃淑娟,「奈米碳纖與奈米碳管合成技術簡介」,化工,第50卷第2期,第18至25頁,2003。
[8] Paul C. Hiemenz and Raj Rajagopalan, Principles of Colloid and Surface Chemistry, 3nd ED, Marcel Dekker, Inc. , New York, pp.405–407, pp. 411–412 (1997).
[9] 吳錦昆,「氧化鋁吸附地下水中砷之研究」,碩士論文,成功大學環境工程學系,台南,1999。
[10] 邱誌忠,「半導體產業高濃度含砷廢水之處理–化學沈降法與活性碳吸附法之評估」,碩士論文,中興大學環境工程學系,台中,2004。
[11] Faust and Samuel Denton, Adsorption Process for Water Treatment Samuel D. Faust and Osman M. Aly, Boston Butterworth, pp.16–22, pp.185–191 (1987).
[12] 劉明翰,「粉狀活性碳吸附氯化汞之研究:操作參數之影響及恆溫吸附模式之建立」,國立中山大學環境工程研究所論文,2001。
[13] 林哲仁,「活性碳之評估與選擇」,環境工程會刊,第六卷第一期,第23–24頁,1995。
[14] 劉曾旭,「活性碳製造技術及應用」,產業調查與技術 第一二七期,第84–88頁,1999。
[15] J. P. Chen, and S. Wu, “ Acid/Base–Treated Activated Carbons: Characterization of Functional Groups and Metal Adsorptive Properties, “Langmuir, 20, pp.2233–2242 (2004).
[16] F. Julien, M. Baudu, and M. Mazet, “ Relationship between Chemical and Physical Surface Properties of Activated Carbon,” Water Research, 32, pp. 3414–3424 (1998).
[17] M. Franz, H. A. Arafat, and N. G. Pinto, ” Effect of Chemical Surface Heterogeneity on the Adsorption Mechanism of Dissolved Aromatics on Activated Carbon,” Carbon, 38, pp.1807–1819 (2000).
[18] J. L. Figueiredo, M. F. R Pereira, M. M. A. Freitas, and J. J. M. Orfao,” Modification of the Surface Chemistry of Activated Carbon,” Carbon, 37, pp.1379–1389 (1999).
[19] L. Li, P. A. Quinlivan, and D. R. U. Knppe, “ Effect of Activated CarbonSurface Chemistry and Pore Structure on the Adsorption of OrganicContaminants from Aqueous Solution,“ Carbon, 40, pp.2085–2100 (2002).
[20] 林哲仁,「淺談活性碳吸附現象之影響因素」,環境工程會刊,第六卷第二期,第14頁,1995。
[21] X. Peng, Y. Li, Z. Luan, Z. Di, H. Wang, B. Tian, and Z. Jia, “ Adsorption of 1, 2–dichlorobenzene from water to carbon nanotubes,” Chemical Physics Letters, 376, pp.154–158 (2003).
[22] F. H. Ko, C. Y. Lee, C. J. Ko, and T. C. Chu, “ Purification of Multi–Walled Nanotubes Through Microwave Heating of Nitric Acid in a Closed Vessel,” Carbon, 43, pp.727–733 (2005).
[23] A. R. Harutyunyan, B. K. Pradhan, J. Chang, G. Chen, and P. C. Eklund, ” Purification of Single–Walled Carbon Nanotubes by Selective Microwave Heating of Catalyst Particles,” Carbon, 106, pp.8671–8675 (2002).
[24] K. B. Shelimov, R. O. Esenaliev, A. G. Rinzler, and C. B. Huffman, “ Purification of Single–Walled Carbon Nanotubes by Ultrasonically Assisted Filtration,” Chemical Physics Letters, 282, pp.429–434 (1998).
[25] L. S. K. Pang, J. D. Saxby, and S.P. Chatfield, “ Thermogravimetric Analysis of Carbon Nanotubes and Nanoparticles,“ Journal of Physical Chemistry, 97, pp.6941–6942 (1993).
[26] S. C. Tsang, P. J. Harris, and M. L. Green, “ Thinning and Opening of Carbon Nanotubes by Oxidation Using Carbon Dioxide,” Nature, 362, 520 (1993).
[27] G. S. Duesberg, M. Burghard, J. Muster, G. Philipp, and S. Roth, “ Seperation of Carbon Nanotubes by Size Exclusion Chromatograpgy,” Chemical Communications, 3, pp.435-436 (1998).
[28] H. Hu, B. Zhao, M. E. Itkis, and R. C. Haddon, “ Nitric Acid Purification of Single–Walled Carbon Nanotubes,” Journal of Physical Chemistry B, 107, pp.13838–13842 (2003).
[29] A. R. Harutyunyan, B. K. Pradhan, J. Chang, G. Chen, and P. C. Eklund, “ Purification of Single–Wall Carbon Nanotubes by Selective Microwave Heating of Catalyst Particles,“ Journal of Physical Chemistry B, 106, pp.8671–8675 (2002).
[30] K. Hernadi, A. Siska, L. T. Nga, L. Forro, and I. Kiricsi, ” Reactivity of Different Kinds of Carbon during Oxidative Purification of Catalytically Prepared Carbon Nanotubes,” Solid State Ionics, 141–142, pp.203–209 (2001).
[31] Y. h. Li, S. Wang, Z. Luan, J. Ding, and C. Xu, “ Adsorption of Cadmium(Ⅱ) from Aqueous Solution by Surface Oxidized Carbon Nanotubes,” Carbon, 41, pp.1057–1062 (2003).
[32] Y. H. Li, S. Wang, J. Wei, X. Zhang, C. Xu, Z. Luan, D. Wu, and B. Wei, “ Lead Adsorption on Carbon Nanotubes,” Chemical Physics Letters, 357, pp.263–266 (2002).
[33] 周貝倫,「純化程序對奈米碳管表面特性影響之研究」,國立中央大學環境工程研究所論文,2006。
[34] C. Lu and H. Chiu, “ Adsorption of Zinc (II) from Water with Purified Carbon Nanotubes,“ Chemical Engineering Science, 61, pp.1138–1145 (2006).
[35] X. Wang, C. Chen, W. Hu, A. Ding, D. Xu, and X. Zhou, “ Sorption of 243Am(Ⅲ) to Multiwall Cabon Nanotubes,” Environmental Science and Technology, 39, pp.2856–2860 (2005).
[36] C. Lu, Y. L. Chung, and K. F. Chang, “ Adsorption of Trihalomethanes from Water with Carbon Nanotubes,” Water Research, 39, pp.1183–1189 (2005).
[37] Y. H. Li, S. Wang, A. Cao, D. Zhao, X. Zhang, C. Xu, Z. Luan, D. Ruan, J. Liang, D. Wu, and B. Wei, “ Adsorption of Fluoride from Water by Amorphous Alumina Supported on Carbon Nanotubes, ”Chemical Physics Letters, 350, pp.412–416 (2001).
[38] D. Q. Yang, J. F. Rochette, and E. Sacher, “ Spectroscopic Evidence for π–π Interaction Poly(diallyl dimethylammonium) Chloride and Multiwalled Carbon Nanotubes,” Journal of Physical Chemistry B, 109, pp.4481–4484 (2005).
[39] C. A. Hunter and J. K. M. Sanders.” The Nature ofπ–πInteractions,” Journal of American Chemical Society, 112, pp.5525–5534 (1990).
[40] J. Zhao, J. P. Lu, J. Han, and C. K. Yang, “ Noncovalent Functionalization of Carbon Nanotubes by Aromatic Organic Molecules,” Applied Physics Letters, 82, pp. 3746–3748 (2003).
[41] R. Q. Long and R. T. Yang, “ Carbon Nanotube as Superior Sorbent for Dioxin Removal,” Journal of the American Chemical Society, 123, pp.2058–2059 (2001).
[42] G. U. Sumanasekera, B. K. Pradhan, H. E. Romero, K. W. Adu, and P. C. Eklund, “ Giant Thermopower Effects from Molecular Physisorption on Carbon Nanotubes,” Physcal Review Letters, 89, 166801 (2002).
[43] R. Niwas, U. Gupta, A. A. Khan, and K. G. Varshney, “ The Adsorption of Phosphamidon on the Surface of Styrene Supported Zirconium (IV) Tungstophosphate: A Thermodynamic Study,” Colloids and Surfaces A: Physicochemical and Engineering Aspects,164, pp.115–119 (2000) |