參考文獻 |
[1] W. Barthlott and C. Neinhuis, “Purity of the Scared Lotus, or Escape from Contamination in Biological Surfaces,” Planta 202 (1997) 1–8.
[2] C. Neinhuis and W. Barthlott, “Characterization and Distribution of Water-Repellent, Self-Cleaning Plant Surfaces,” Annals of Botany 79 (6) (1997) 667–77.
[3] T. Nishino, M. Meguro, K. Nakamae, M. Matsushita and Y. Ueda, “The Lowest Surface Free Energy Based on-CF3 Alignment,” Langmuir 15 (13) (1999) 4321–4323.
[4] E. Puukilainen, H. K. Koponen, Z. Xiao, S. Suvanto and T. A. Pakkanen, “Nanostructured and Chemically Modified Hydrophobic Polyolefin Surfaces,” Colloids and Surfaces A: Physicochemical and Engineering Aspects 287 (1-3) (2006) 175–181.
[5] J. Bico, C. Marzolin and D. Quere, “Pearl Drops,” EPL 47 (1999) 220.
[6] M. Barberoglou, V. Zorba, A. Pagozidis, C. Fotakis and E. Stratakis, “Electrowetting Properties of Micro/Nanostructured Black Silicon,” Langmuir 26(15) (2010) 13007–13014.
[7] S. Shibuichi, T. Onda, N. Satoh, K. Tsujii, “Super Water-Repellent Surfaces Resulting from Fractal Structure,” The Journal of Physical Chemistry 100 (50) (1996) 19512–19517.
[8] Z. Yoshimitsu, A. Nakajima, T. Watanabe and K. Hashimoto, “Effects of Surface Structure on the Hydrophobicity and Sliding Behavior of Water Droplets,” Langmuir 18(15) (2002) 5818–5822.
[9] 丁志明等編著,奈米科技:基礎、應用與實作,初版,臺北縣五股鄉,高立,2005年。
[10] 呂宗昕,圖解奈米科技與光觸媒,初版,臺北市,商周出版,2003年。
[11] 呂宗昕,全面進攻奈米科技與太陽電池,第一版,臺北市,天下遠見,2009年。
[12] 陳富亮編著,最新奈米光觸媒應用技術,初版,臺北縣五股鄉,普林斯頓,2003年。
[13] 垰田博史著,張晶、楊健譯,光觸媒圖解,初版,臺北市,商周出版,2003年。
[14] 林有銘,無所不在的環境清潔工奈米光觸媒,科學發展,408期,2006年。
[15] W. Barthlott and C. Neinhuis, “Purity of the Scared Lotus, or Escape from Contamination in Biological Surfaces,” Planta 202 (1997) 1–8.
[16] S. Leijonmarck, A. Cornell, G. Lindbergh and L. Wågberg, “Single-Paper Flexible Li-Ion Battery Cells Through a Paper-Making Process Based on Nano-Fbrillated Cellulose,” J. Mater. Chem. A (2013) 4671–4677.
[17] O. Karaagac, H. Kockar and M. Alper, “Electrodeposited Cobalt Films: TheEffect of Deposition Potentials on the Film Properties,” J. Optel. Adv. Mater. 15 (2013) 1412–1416.
[18] P. M. Rao, L. Cai, C. Liu, I. S. Cho, C. H. Lee, J. M. Weisse, P. Yang and X. Zheng, “Simultaneously Efficient Light Absorption and Charge Separation in WO3/BiVO4 Core/Shell Nanowire Photoanode for Photoelectrochemical Water Oxidation,” Nano Lett. 14 (2014) 1099−1105.
[19] R. Rurali, M. Palummo and X. Cartoixà1, “Convergence Study of Neutral and Charged Defect Formation Energies in Si Nanowires,” Physical Review B 81 (2010) 235304 1–6.
[20] W. Wang, Y. Xie, Y. Wang, H. Du, C. Xia, F. Ti, “Glucose Biosensor Based on Glucose Oxidase Immobilized on Unhybridized Titanium Dioxide Nanotube Arrays,” Microchim Acta 181 (2014) 381–387.
[21] H. W. Shim, D. K. Lee, I. S. Cho, K. S. Hong and D. W. Kim, “Facile Hydrothermal Synthesis of Porous TiO2 Nanowire Electrodes with High-Rate Capability for Li Ion Batteries,” Nanotechnology 21 (2010) 255706 1–9.
[22] D. Gong, C. A. Grimes, O. K. Varghese, W. Hu, R. S. Singh, Z. Chen and E. C. Dickey, “Titanium Oxide Nanotube Arrays Prepared by Anodic Oxidation,” J. Mater. Res. 16 (2001) 12.
[23] C. Y. Tsai, C. Y. Wu, K. H. Chang and P. T. Lee, “ Slab Thickness Dependence of Localized Surface Plasmon Resonance Behavior in Gold Nanorings,” Plasmonics 8 (2013) 1011–1016.
[24] J. Aizpurua, P. Hanarp, D. S. Sutherland, M. Ka¨ll, G. W. Bryant and F. J. Garcı´a de Abajo, “Optical Properties of Gold Nanorings,” Phy. Rev. Lett. 90 (2003) 5.
[25] S. Horiuchi, T. Gotou, M. Fujiwara, R. Sotoaka, M. Hirata, K. Kimoto, T. Asaka, T. Yokosawa, Y. Matsui, K. Watanabe and M. Sekita, “Carbon Nanofilm with a New Structure and Property,” Jpn. J. Appl. Phys. 42 (2003) L1073.
[26] L. Chen, K. Yang, H. Liu and X. Wang, “Carbon Nanotube Supported Pd Catalyst for Liquid-Phase Hydrodehalogenation of Bromobenzene,” Carbon 46 (2008) 2137–2139.
[27] H. Wang, B. Hu, L. Zhang, M. Li, E. Ja, and Z. Liu, “Enhanced Structural Ordering and Coercivity in FePt Nanowire Arrays by Addition of Zn,” Journal of Magnetism and Magnetic Materials 362 (2014) 47–51.
[28] S. K. Srivastava, D. Kumar, S. W. Schmitt, K. N. Sood, S. H. Christiaansen and P. K. Singh, “Large Area Fabrication of Vertical Silicon Nanowire Arrays by Silver-Assisted Single-Step Chemical Etching and Their Formation Kinetics,” Nanotechnology 25 (2014) 175601.
[29] U. Dembereldorj, S. Y. Choi, E. O. Ganbold, N. W. Song, D. Kim, J. Choo, S. Y. Lee, S. Kim and S. W. Joo, “Gold Nanorod-Assembled Pegylated Graphene-Oxide Nanocomposites for Photothermal Cancer Therapy,” Photochemistry and Photobiology 90 (2014) 659–666.
[30] S. H. Huang, S. C. Twan, S. L. Cheng, T. Lee, J. C. Hu, L. T. Chen and S. W. Lee, “Influence of Al Addition on Phase Transformation and Thermal Stability of Nickel Silicides on Si(001),” Journal of Alloys and Compounds 586 (2014) S362–S367.
[31] Y. Peng, H. L. Zhang, S. L. Pan and H. L. Li, “Magnetic Properties and Magnetization Reversal of α-Fe Nanowires Deposited in Alumina Film,” J. Appl.Phys. 87 (2000) 7405.
[32] H. Zeng, M. Zheng, R. Skomski, D. J. Sellmyer, Y. Liu, L. Menon and S. Bandyopadhyay, “Magnetic Properties of Self-Assembled Co Nanowires of Varying Length and Diameter,”J. Appl. Phys. 87 (2000) 4718.
[33] G. J. Strijkers, J. H. J. Dalderop, M. A. A. Broeksteeg, H. J. M. Swagten and W. J. M. De Jonge, “Structure and Magnetization of Arrays of Electrodeposited Co Wires in Anodic Alumina,” J. Appl. Phys. 86 (1999) 5141.
[34] P. Raksa, A. Gardchareon, T. Chairuangsri, P. Mangkorntong, N. Mangkorntong and S. Choopun, “Ethanol Sensing Properties of CuO Nanowires Prepared by an Oxidation Reaction,” Ceram. Int. 35 (2009) 649–652.
[35] G. Amin, M. H. Asif, A Zainelabdin, S. Zaman, O. Nur and M. Willander, “Influence of pH, Precursor Concentration, Growth Time, and Temperature on the Morphology of ZnO Nanostructures Grown by the Hydrothermal Method,” Nanomaterials. 10 (2011) 269692.
[36] Z. L. Jin, X. J. Zhang, Y. X. Li, S. B. Li and G. X. Lu, “5.1% Apparent Quantum Efficiency for Stable Hydrogen Generation over Eosin-Sensitized CuO/TiO2 Photocatalyst under Visible Light Irradiation,” Catal. Commun. 8 (2007) 1267–1273.
[37] Q. L. Bao, C. M. Li, L. Liao, H. B. Yang, W. Wang, C. Ke, Q. L. Song, H. F. Bao, T. Yu, K. P. Loh and J. Guo, “Electrical Transport and Photovoltaic Effects of Core-Shell CuO/C60 Nanowire Heterostructure,” Nanotechnology 20 (2009) 065203 1–8.
[38] G. Zou, H. Li, D. Zhang, K. Xiong, C. Dong and Y. Qian, “Well-Aligned Arrays of CuO Nanoplatelets,” J. Phys. Chem. B 110 (2006) 1632–1637.
[39] H. J. Nam, T. Sasaki and N. Koshizaki, “Optical CO Gas Sensor Using a Cobalt Oxide Thin Film Prepared by Pulsed LaserDeposition under Various Argon Pressures,” J. Phys. Chem. B. 110 (2006) 23081–23084.
[40] L. Fu, Z. Liu, Y. Liu, B. Han, P. Hu, L. Cao and D. Zhu, “Beaded Cobalt Oxide Nanoparticles along Carbon Nanotubes: Towards More Highly Integrated Electronic Devices,” Advanced Materials 17 (2005) 217–22.
[41] S. H. Yi, S. K. Choi, J. M. Jang, J. A. Kim and W. G. Jung, “Low-Temperature Growth of ZnO Nanorods by Chemical Bath Deposition,” J. colloid interface Sci. 313 (2007) 705–710.
[42] Z. K. Tang, G. K. L. Wong and P. Yu, “Room-Temperature Ultraviolet Laser Emission from Self-Assembled ZnO Microcrystallite Thin Films,” Appl. Phys. Lett. 72 (1998) 3270–3272.
[43] M. Mandal, S. K. Ghosh, S. Kundu, K. Esumi and T. Pal, “UV Photoactivation for Size and Shape Controlled Synthesis and Coalescence of Gold Nanoparticles in Micelles,” Langmuir 18 (2002) 7792–7797.
[44] N. R. Jana, Y. Chen and X. Peng, “Size- and Shape-Controlled Magnetic (Cr, Mn,Fe, Co, Ni) Oxide Nanocrystals via a Simple and General Approach,” Chem. Mater. 16 (2004) 3931–3935.
[45] L. H. Wang, X. Z. Zhang, S. Q. Zhao, G. Y. Zhou, Y. L. Zhou and J. J. Qi, “Synthesis of Well-Aligned ZnO Nanowires by Simple Physical Vapor Deposition on C-Oriented ZnO Thin Films Without Catalysts or Additives,” Appl. Phys. Lett. 86 (2005) 024108 1–3.
[46] Y. C. Kong, D. P. Yu, B. Zhang, W. Fang and S. Q. Feng, “Ultraviolet-Emitting ZnO Nanowires Synthesized by a Physical Vapor Deposition Approach,” Appl. Phys. Lett. 78 (2001) 407–409.
[47] C. H. Hsiao, S. J. Chang, S. B. Wang, S. P. Chang, T. C. Li, W. J. Lin, C. H. Ko, T.M. Kuan and B. R. Huang, “ZnSe Nanowire Photodetector Prepared on Oxidized Silicon Substrate by Molecular-Beam Epitaxy,” J. Electrochem. Soc. 156 (2009) J73–J76.
[48] J. Thangala, S. Vaddiraju, S. Malhotra, V. Chakrapani and M. K. Sunkara, “A Hot-Wire Chemical Vapor Deposition (HWCVD) Method for Metal Oxide and Their Alloy Nanowire Arrays,” Thin Solid Films 517 (2009) 3600–3605.
[49] J. B. Baxtera and E. S. Aydil, “Metallorganic Chemical Vapor Deposition of ZnO Nanowires from Zinc Acetylacetonate and Oxygen,” J. Electrochem. Soc. 156 (2009) H52–H58.
[50] J. Lao, J. Huang, D. Wang and Z. Ren, “Self-Assembled In2O3 Nanocrystal Chains and Nanowire Networks,” Adv. Mater. 16 (2004) 65–69.
[51] E. Zhang, Y. Tang, Y. Zhang and C. Guo, “Synthesis and Photoluminescence Property of Silicon Carbon Nanowires Synthesized by the Thermal Evaporation Method,” Physica E 41 (2009) 655–659.
[52] M. X. Qiu, Z. Z. Ye, J. G. Lu, H. P. He, J. Y. Huang, L. P. Zhu and B. H. Zhao, “Growth and Properties of ZnO Nanorod and Nanonails by Thermal Evaporation,” Appl. Surf. Sci. 252 (2009) 3972–3976.
[53] H. B. Xu, H. Z. Chen, W. J. Xu and M. Wang, “Fabrication of Organic Copper Phthalocyanine Nanowire Arrays via a Simple AAO Template-Based Electrophoretic Deposition,” Chem. Phys. Lett. 412 (2005) 294–298.
[54] J. C. Hulteen and C. R. Martin, “A General Template-Based Method for the Preparation of Nanomaterials,” J. Mater. Chem. 7 (1997) 1075–1087.
[55] H. J. Fan, W. Lee, R. Hauschild, M. Alexe, G. L. Rhun, R. Scholz, A. Dadgar, K. Nielsch, H. Kalt, A. Krost, M. Zacharias and U. Gösele, “Template-Assisted Large-Scale Ordered Arrays of ZnO Pillars for Optical and Piezoelectric Applications,” Small 2 (2006) 561–568.
[56] J. Zhao, Z. G. Jin, T. Li and X. X. Liu, “Nucleation and Growth of ZnO Nanorods on the ZnO-Coated Seed Surface by Solution Chemical Method,” J. Eur. Ceram. Soc. 26 (2006) 2769–2775.
[57] A. Y. Zhang, Q. Ma, M. K. Lu, G. W. Yu, Y. Y. Zhou and Z. F. Qiu, “Copper-Indium Sulfide Hollow Nanospheres Synthesized by a Facile Solution-Chemical Method,” Cryst. Growth Des. 8 (2008) 2402–2405.
[58] X. Jiang, T. Herricks and Y. Xia, “CuO Nanowires Can Be Synthesized by Heating Copper Substrates in Air,” Nano Lett. 2 (2002) 1333–1338.
[59] C. H. Xu, C. H. Woo and S. Q. Shi, “Formation of CuO Nanowires on Cu Foil,” Chem. Phys. Lett. 399 (2004) 62–66.
[60] K. Zhang, C. Rossi, P. Alphonse and C. Tenailleau, “Synthesis of NiO Nanowalls by Thermal Treatment of Ni Film Deposited onto a Stainless Steel Substrate,” Nanotechnology 19 (2008) 155605.
[61] Z. Qiao, D. Xu, F. Nie, G. Yang and K. Zhang, “Controlled Facile Synthesis, Growth Mechanism, and Exothermic Properties of Large-Area Co3O4 Nanowalls and Nanowires on Silicon Substrates,” Journal of Applied Physics 112 (2012) 014310.
[62] D. H. Ha, L. M. Moreau, S. Honrao, R. G. Hennig and R. D. Robinson, “The Oxidation of Cobalt Nanoparticles into Kirkendall-Hollowed CoO and Co3O4: The Diffusion Mechanisms and Atomic Structural Transformations,” J. Phys. Chem. C. 117 (2013) 14303−14312.
[63] C. Florica, N. Preda, A. Costas, I. Zgura and I. Enculescu, “ZnO Nanowires Grown Directly on Zinc Foils by Thermal Oxidation in Air: Wetting and Water Adhesion Properties,” Materials Letters 170 (2016) 156–159.
[64] C. X. Zhao, Y. F. Li, J. Zhou, L. Y. Li, S. Z. Deng, N. S. Xu and J. Chen, “Large-Scale Synthesis of Bicrystalline ZnO Nanowire Arrays by Thermal Oxidation of Zinc Film: Growth Mechanism and High-Performance Field Emission,” Cryst. Growth Des. 13 (2013) 2897–2905.
[65] S. Xie, Y. Zhao and Y. Jiang, “Laser-Induced Hydrophobicity on Single Crystal Zinc Oxide Surface,” Applied Surface Science 263 (2012) 405–409.
[66] J. Zhang, Y. Liu, Z. Wei and J. Zhang, “Mechanism for Wettability Alteration of ZnO Nanorod Arrays via Thermal Annealing in Vacuum and Air,” Applied Surface Science 265 (2013) 363–368.
[67] X. Q. Meng, D. X. Zhao, J. Y. Zhang, D. Z. Shen, Y. M. Lu, L. Dong, Z. Y. Xiao, Y. C. Liu and X.W. Fan, “Wettability Conversion on ZnO Nanowire Arrays Surface Modified by Oxygen Plasma Treatment and Annealing,” Chemical Physics Letters 413 (2005) 450–453.
[68] Y. Kobayashi and S. Adachi, “Properties of Si Nanowires Synthesized by Galvanic Cell Reaction,” Japanese Journal of Applied Physics 49 (2010) 075002.
[69] M. L. Zhang, K. Q. Peng, X. Fan, J. S. Jie, R. Q. Zhang, S. T. Lee and N. B. Wong, “Preparation of Large-Area Uniform Silicon Nanowires Arrays through Metal-Assisted Chemical Etching,” J. Phys. Chem. C 112 (2008) 4444–4450.
[70] L. Lin, S. Guo, X. Sun, J. Feng and Y. Wang, “Synthesis and Photoluminescence Properties of Porous Silicon Nanowire Arrays,” Nano. Res. Lett. 5 (2010) 1822–1828.
[71] B. Ozdemir, M. Kulakci, R. Turan and H. E. Unalan, “Effect of Electroless Etching Parameters on the Growth and Reflection Properties of Silicin Nanowires,” Nanotechnology 22(2011) 155606.
[72] J. S. Rowlinson and B. Widom, “Molecular Theory of Capillarity,” Oxford. 66 (1982) 816.
[73] R. N. Wenzel, “Resistance of Solid Surfaces to Wettingby Water,” Industrial & Engineering Chemistry 28 (1936) 988.
[74] A. B. D. Cassie, S. Baxter, “Wettability of Porous Surfaces,” Trans. Faraday Soc. 40 (1944) 546.
[75] P. W. Chi, C. W. Su, B. H. Jhuo and D. H. Wei, “Photoirradiation Caused Controllable Wettability Switching of Sputtered Highly Aligned c-Axis-Oriented Zinc Oxide Columnar Films,” International Journal of Photoenergy 2014 (2014) 765209.
[76] J. Y. Zheng, S. H. Bao, Y. Guo and P. Jin, “Natural Hydrophobicity and Reversible Wettability Conversion of Flat Anatase TiO2 Thin Film,” ACS Appl. Mater. Interfaces 6 (2014) 1351–1355.
[77] B. J. Li, L. J. Huang, M. Zhu and N. F. Ren, “Reversible Wettability Control of ZnO Thin Films Synthesized by Hydrothermal Precess on Different Buffer Layers,” Materials Letters 110 (2013) 160–163.
[78] B. Y. Zhang, S. X. Lu, W. G. Xu and Y. Y. Cheng, “Controllable Wettability and Morphology of Electrodeposited Surfaces on Zinc Substrates,” Applied Surface Science 360 (2016) 904–914.
[79] J. Yang, Z. Z. Zhang, X. H. Men, X. H. Xu and X. T. Zhu, “Reversible Superhydrophobicity to Superhydrophilicity Switching of a Carbon Nanotube Film via Alternation of UV Irradiation and Dark Storage,” Langmuir 26 (2010) 10198–10202.
[80] J. Y. Long, M. L. Zhong, P. X. Fan, D. W. Gong and H. J. Zhang, “Wettability Conversion of Ultrafast Structured Copper Surface,” Journal of Laser Applications 27 (2015) S29107.
[81] J. Y. Long, M. L. Zhong, H. J. Zhang, P. X. Fan, “Superhydrophilicity to Superhydrophobicity Transition of Picosecond Laser Microstructured Aluminum in Ambient Air,” Journal of Colloid and Interface Science 441 (2015) 1–9.
[82] B. Yan, J. Tao, C. Pang, Z. Zheng, Z. Shen, C. H. A. Huan and T. Yu, “Reversible UV-Light-Induced Ultrahydrophobic-to-Ultrahydrophilic Transition in an α-Fe2O3 Nanoflakes Film,” Langmuir 24 (2008) 10569–10571.
[83] H. Luo, J. Ma, P. Wang, J. Bai and G. Jing, “Two-Step Wetting Transition on ZnO Nanorod Arrays,” Applied Surface Science 347 (2015) 867–874.
[84] Y. S. Liu, W. W. Chen, S. H. Wei and W. Gao, “TiO2/ZnO Nanocomposite, ZnO/ZnO Bi-Level Nanostructure and ZnO Nanorod Arrays: Microstructure and Time-Affected Wettability Change in Ambient Conditions,” RSC Adv. 4 (2014) 30658–30065.
[85] S. J. Xie, Y. Zhao and Y. J. Jiang, “Laser-Induced Hydrophobicity on Single Crystal Zinc Oxide Surface,” Applied Surface Science 263 (2012) 405–409.
[86] S. L. Cheng, J. H. Syu, S. Y. Liao, C. F. Lin and P. Y. Yeh, “Growth Kinetics and Wettability Conversion of Vertically-Aligned ZnO Nanowires Synthesized by a Hydrothermal Method,” RSC Adv. 5 (2015) 67752–67758.
[87] 潘純華,張衛红,陳芬等,ATR紅外光譜法在高分子材料表面成份分析上的應用,廣州化工,28 期,2000 年。
[88] 江艷,沈怡,武培怡,ATR-FTIR光譜技術在聚合物膜研究中的應用,化學進展,19 期,2007 年。
[89] 吳瑾光,近代傅立葉變換紅外光譜技術及應用,第一版,北京,科學技術文獻出版社,1994年。
[90] 薛奇,高分子結構研究中的光譜方法,北京,高等教育出版社,1995年。
[91] 曾泳淮,林樹昌,分析化學(儀器分析部分),第二版,北京,高等教育出版社,2004年。 |