常壓微電漿系統之診斷及進行高分子薄膜沉積之製程研究

Chih-Chun Wang; 王誌君

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/65004

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	徐振哲(Cheng-Che Hsu)
dc.contributor.author	Chih-Chun Wang	en
dc.contributor.author	王誌君	zh_TW
dc.date.accessioned	2021-06-16T23:14:33Z	-
dc.date.available	2017-08-28
dc.date.copyright	2012-08-28
dc.date.issued	2012
dc.date.submitted	2012-08-01
dc.identifier.citation	1. U. Kogelschatz, ' Filamentary, patterned, and diffuse barrier discharges ', Plasma Science, IEEE Transactions on, 30 (4), 1400-1408 (2002). 2. N. Gherardi, G. Gouda, E. Gat, A. Ricard and F. Massines, ' Transition from glow silent discharge to micro-discharges in nitrogen gas ', Plasma Sources Sci. Technol., 9 (3), 340-346 (2000). 3. K. H. Becker, K. H. Schoenbach and J. G. Eden, ' Microplasmas and applications ', J. Phys. D-Appl. Phys., 39 (3), R55-R70 (2006). 4. K. Tachibana, ' Current status of microplasma research ', IEEJ Trans. Electr. Electron. Eng., 1 (2), 145-155 (2006). 5. M. A. Lieberman and A. J. Lichtenberg, 'Principles of Plasma Discharges and Materials Processing. ', New York: Wiley (2005). 6. F. Iza, G. J. Kim, S. M. Lee, J. K. Lee, J. L. Walsh, Y. T. Zhang and M. G. Kong, ' Microplasmas: Sources, particle kinetics, and biomedical applications ', Plasma Process. Polym., 5 (4), 322-344 (2008). 7. K. H. Schoenbach, A. ElHabachi, W. H. Shi and M. Ciocca, ' High-pressure hollow cathode discharges ', Plasma Sources Sci. Technol., 6 (4), 468-477 (1997). 8. R. H. Stark and K. H. Schoenbach, ' Direct current high-pressure glow discharges ', Journal of Applied Physics, 85 (4), 2075-2080 (1999). 9. D. D. Hsu and D. B. Graves, ' Microhollow cathode discharge stability with flow and reaction ', J. Phys. D-Appl. Phys., 36 (23), 2898-2907 (2003). 10. X. Aubert, G. Bauville, J. Guillon, B. Lacour, V. Puech and A. Rousseau, ' Analysis of the self-pulsing operating mode of a microdischarge ', Plasma Sources Sci. Technol., 16 (1), 23-32 (2007). 11. A. Rousseau and X. Aubert, ' Self-pulsing microplasma at medium pressure range in argon ', J. Phys. D-Appl. Phys., 39 (8), 1619-1622 (2006). 12. C. Lazzaroni, P. Chabert, A. Rousseau and N. Sadeghi, ' The excitation structure in a micro-hollow cathode discharge in the normal regime at medium argon pressure ', J. Phys. D-Appl. Phys., 43 (12)(2010). 13. C. Lazzaroni, P. Chabert, A. Rousseau and N. Sadeghi, ' Sheath and electron density dynamics in the normal and self-pulsing regime of a micro hollow cathode discharge in argon gas ', Eur. Phys. J. D, 60 (3), 555-563 (2010). 14. 李杰倫, ' 常壓微中空陰極放電及其量測 ' 碩士論文, 國立東華大學, 2009. 15. V. I. Gibalov and G. J. Pietsch, ' The development of dielectric barrier discharges in gas gaps and on surfaces ', J. Phys. D-Appl. Phys., 33 (20), 2618-2636 (2000). 16. M. J. Kushner, ' Modelling of microdischarge devices: plasma and gas dynamics ', J. Phys. D-Appl. Phys., 38 (11), 1633-1643 (2005). 17. U. Kogelschatz, ' Dielectric-barrier discharges: Their history, discharge physics, and industrial applications ', Plasma Chem. Plasma Process., 23 (1), 1-46 (2003). 18. J. Waskoenig, D. O'Connell, V. Gathen, J. Winter, S. J. Park and J. G. Eden, ' Spatial dynamics of the light emission from a microplasma array ', Applied Physics Letters, 92 (10)(2008). 19. D. S. Lee, K. Tachibana, H. J. Yoon and H. J. Lee, ' Enhancement of Optical Emission by Floating Electrodes in a Planar Microdischarge Cell ', Jpn. J. Appl. Phys., 48 (5)(2009). 20. G. R. Bardajee, A. Pourjavadi, R. Soleyman and N. Sheikh, ' Irradiation mediated synthesis of a superabsorbent hydrogel network based on polyacrylamide grafted onto salep ', Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 266 (18), 3932-3938 (2008). 21. K. Tachibana, S. Kawai, H. Asai, N. Kikuchi and S. Sakamoto, ' Characteristics of Ne-Xe microplasma in unit discharge cell of plasma display panel equipped with counter sustain electrodes and auxiliary electrodes ', J. Phys. D-Appl. Phys., 38 (11), 1739-1749 (2005). 22. P. Ramasamy, B. Nikita and A. Peter, ' Amorphous carbon film deposition on the inner surface of tubes using atmospheric pressure pulsed filamentary plasma source ', Journal of Physics D: Applied Physics, 44 (35), 355206 (2011). 23. R. Pothiraja, N. Bibinov and P. Awakowicz, ' Pulsed corona plasma source characterization for film deposition on the inner surface of tubes ', J. Phys. D-Appl. Phys., 43 (49)(2010). 24. Y. Hiroyuki, ' Thin film coatings on capillary inner walls by microplasma ', Vacuum, 84 (5), 559-563 (2009). 25. S. A. Wright and Y. B. Gianchandani, ' Contaminant gas removal using thin-film Ti electrode microdischarges ', Applied Physics Letters, 95 (11)(2009). 26. L. G. Meng, H. F. Liang, C. L. Liu and Z. H. Liang, ' A Line Array of Microplasma Devices With Coplanar Electrodes Operating in Argon ', Ieee Transactions on Plasma Science, 36 (5), 2788-2794 (2008). 27. S. A. Wright and Y. B. Gianchandani, ' Discharge-Based Pressure Sensors for High-Temperature Applications Using Three-Dimensional and Planar Microstructures ', J. Microelectromech. Syst., 18 (3), 736-743 (2009). 28. P. Carazzetti and H. R. Shea, ' Electrical breakdown at low pressure for planar microelectromechanical systems with 10-to 500-mu m gaps ', J. Micro-Nanolithogr. MEMS MOEMS, 8 (3)(2009). 29. J. G. Eden, S. J. Park, N. P. Ostrom and K. F. Chen, ' Recent advances in microcavity plasma devices and arrays: a versatile photonic platform ', J. Phys. D-Appl. Phys., 38 (11), 1644-1648 (2005). 30. J. G. Eden, S. J. Park, N. P. Ostrom, S. T. McCain, C. J. Wagner, B. A. Vojak, J. Chen, C. Liu, P. von Allmen, F. Zenhausern, D. J. Sadler, C. Jensen, D. L. Wilcox and J. J. Ewing, ' Microplasma devices fabricated in silicon, ceramic, and metal/polymer structures: arrays, emitters and photodetectors ', J. Phys. D-Appl. Phys., 36 (23), 2869-2877 (2003). 31. J. Chen, S. J. Park, Z. F. Fan, J. G. Eden and C. Liu, ' Development and characterization of micromachined hollow cathode plasma display devices ', J. Microelectromech. Syst., 11 (5), 536-543 (2002). 32. J. W. Frame and J. G. Eden, ' Planar microdischarge arrays ', Electron. Lett., 34 (15), 1529-1531 (1998). 33. H. Boettner, J. Waskoenig, D. O'Connell, T. L. Kim, P. A. Tchertchian, J. Winter and V. Schulz-von der Gathen, ' Excitation dynamics of micro-structured atmospheric pressure plasma arrays ', J. Phys. D-Appl. Phys., 43 (12)(2010). 34. J. W. Frame, D. J. Wheeler, T. A. DeTemple and J. G. Eden, ' Microdischarge devices fabricated in silicon ', Applied Physics Letters, 71 (9), 1165-1167 (1997). 35. S. J. Park, J. G. Eden and K. H. Park, ' Carbon nanotube-enhanced performance of microplasma devices ', Applied Physics Letters, 84 (22), 4481-4483 (2004). 36. J. Zhang and A. Wang, ' Study on superabsorbent composites. IX: Synthesis, characterization and swelling behaviors of polyacrylamide/clay composites based on various clays ', Reactive and Functional Polymers, 67 (8), 737-745 (2007). 37. S. C. Brown, 'Basic Data of Plasma Physics ', Massachusetts Institute of Technology, Cambridge, Massachusetts, and John Wiley & Sons, Inc., New York, (1959). 38. S. Mohr, B. L. Du, D. Luggenholscher and U. Czarnetzki, ' Investigations on the afterglow of a thin cathode discharge in argon at atmospheric pressure ', J. Phys. D-Appl. Phys., 43 (29)(2010). 39. B. Mitra and Y. B. Gianchandani, ' The detection of chemical vapors in air using optical emission spectroscopy of pulsed microdischarges from two- and three-electrode microstructures ', IEEE Sens. J., 8 (7-8), 1445-1454 (2008). 40. Y. B. Gianchandani, S. A. Wright, C. K. Eun, C. G. Wilson and B. Mitra, ' Exploring microdischarges for portable sensing applications ', Anal. Bioanal. Chem., 395 (3), 559-575 (2009). 41. S. O. Kim, ' Microplasma device utilizing SU-8 photoresist as a barrier rib ', Ieee Transactions on Plasma Science, 36 (4), 1244-1245 (2008). 42. D. S. Lee, O. Sakai and K. Tachibana, ' Mode Change Observed on Spatial Distribution of Microplasma Emission in a Microdischarge Cell with a Floating Electrode ', Jpn. J. Appl. Phys., 48 (10)(2009). 43. K. Becker, A. Koutsospyros, S. M. Yin, C. Christodoulatos, N. Abramzon, J. C. Joaquin and G. Brelles-Marino, ' Environmental and biological applications of microplasmas ', Plasma Phys. Control. Fusion, 47, B513-B523 (2005). 44. 林東毅, ' 利用毛細管式微電漿系統對懸浮菌液之滅菌研究 ' 碩士論文, 國立成功大學, 2010. 45. U. Schnabel, T. Maucher, J. Kohnlein, W. Volkwein, R. Niquet, I. Trick, M. Stieber, M. Muller, H. P. Werner, J. Ehlbeck, C. Oehr and K. D. Weltmann, ' Multicentre Trials for Decontamination of Fine-Lumen PTFE Tubes Loaded with Bacterial Endospores by Low and Atmospheric Pressure Plasma ', Plasma Process. Polym., 9 (1), 37-47 (2012). 46. M. Polak, J. Winter, U. Schnabel, J. Ehlbeck and K.-D. Weltmann, ' Innovative Plasma Generation in Flexible Biopsy Channels for Inner-Tube Decontamination and Medical Applications ', Plasma Process. Polym., 9 (1), 67-76 (2012). 47. R. Foest, E. Kindel, H. Lange, A. Ohl, M. Stieber and K. D. Weltmann, ' RF Capillary Jet - a Tool for Localized Surface Treatment ', Contributions to Plasma Physics, 47 (1-2), 119-128 (2007). 48. L. Cao, B. D. Ratner and T. A. Horbett, ' Plasma deposition of tetraglyme inside small diameter tubing: Optimization and characterization ', Journal of Biomedical Materials Research Part A, 81A (1), 12-23 (2007). 49. H. Yoshiki, K. Abe and T. Mitsui, ' SiO2 thin film deposition on the inner surface of a poly(tetra-fluoroethylene) narrow tube by atmospheric-pressure glow microplasma ', Thin Solid Films, 515 (4), 1394-1399 (2006). 50. R. Wei, C. Rincon, T. L. Booker and J. H. Arps, ' Magnetic field enhanced plasma (MFEP) deposition of inner surfaces of tubes ', Surface and Coatings Technology, 188-189 (0), 691-696 (2004). 51. J. L. Lauer, J. L. Shohet, R. M. Albrecht, C. Pratoomtong, R. Murugesan, R. D. Bathke, S. Esnault, J. S. Malter, S. B. Shohet and U. H. von Andrian, presented at the Plasma Science, 2004. ICOPS 2004. IEEE Conference Record - Abstracts. The 31st IEEE International Conference on, 2004 (unpublished). 52. R. Prat, Y. J. Koh, Y. Babukutty, M. Kogoma, S. Okazaki and M. Kodama, ' Polymer deposition using atmospheric pressure plasma glow (APG) discharge ', Polymer, 41 (20), 7355-7360 (2000). 53. H. Fujiyama, ' Inner coating of long-narrow tube by plasma sputtering ', Surf. Coat. Technol., 131 (1-3), 278-283 (2000). 54. Y. Uchikawa, S. Sugimoto, K. Kuwahara, H. Fujiyama and H. Kuwahara, ' Titanium coating of the inner of a 1 m long narrow tube by double-ended anode coaxial magnetron-pulsed plasmas ', Surf. Coat. Technol., 112 (1-3), 185-188 (1999). 55. Y. Babukutty, R. Prat, K. Endo, M. Kogoma, S. Okazaki and M. Kodama, ' Poly(vinyl chloride) Surface Modification Using Tetrafluoroethylene in Atmospheric Pressure Glow Discharge ', Langmuir, 15 (20), 7055-7062 (1999). 56. R. Hytry, W. Moller, R. Wilhelm and A. v. Keudell, ' Moving-coil waveguide discharge for inner coating of metal tubes ', Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 11 (5), 2508-2517 (1993). 57. W.-C. Gu, G.-H. Lv, H. Chen, G.-L. Chen, W.-R. Feng and S.-Z. Yang, ' PEO protective coatings on inner surface of tubes ', Surface and Coatings Technology, 201 (15), 6619-6622 (2007). 58. M. Deilmann, S. Theis and P. Awakowicz, ' Pulsed microwave plasma polymerization of silicon oxide ﬁlms: Application of efficient permeation barriers on polyethylene terephthalate ', Surface and Coatings Technology, 202 (10), 1911-1917 (2008). 59. L. Wang, L. Huang, Y. Wang, Z. Xie and X. Wang, ' Duplex diamond-like carbon film fabricated on 2Cr13 martensite stainless steel using inner surface ion implantation and deposition ', Surface and Coatings Technology, 202 (14), 3391-3395 (2008). 60. A. Agiral, L. Lefferts and J. Gardeniers, ' Catalyst Activation by Microplasma for Carbon Nanofiber Synthesis in a Microreactor ', Plasma Science, IEEE Transactions on, 37 (6), 985-992 (2009). 61. M. Deilmann, H. Halfmann, S. Steves, N. Bibinov and P. Awakowicz, ' Silicon Oxide Permeation Barrier Coating and Plasma Sterilization of PET Bottles and Foils ', Plasma Process. Polym., 6 (S1), S695-S699 (2009). 62. B. Jaleh, M. S. Madad, S. Habibi, P. Wanichapichart and M. F. Tabrizi, ' Evaluation of physico-chemical properties of plasma treated PS-TiO(2) nanocomposite film ', Surf. Coat. Technol., 206 (5), 947-950 (2011). 63. K. Baba, R. Hatada, S. Flege and W. Ensinger, ' Deposition of Diamond-Like Carbon Films on Inner Wall Surfaces of Millimeter-Size-Diameter Steel Tubes by Plasma Source Ion Implantation ', Plasma Science, IEEE Transactions on, 39 (11), 3140-3143 (2011). 64. F. Alba-Elias, J. Ordieres-Mere and A. Gonzalez-Marcos, ' Deposition of thin-films on EPDM substrate with a plasma-polymerized coating ', Surf. Coat. Technol., 206 (2-3), 234-242 (2011). 65. H. Yoshiki and T. Saito, ' Preparation of TiO[sub 2] thin films on the inner surface of a quartz tube using atmospheric-pressure microplasma ', Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films, 26 (3), 338-343 (2008). 66. H. Yoshiki and T. Mitsui, ' TiO2 thin film coating on a capillary inner surface using atmospheric-pressure microplasma ', Surface and Coatings Technology, 202 (22-23), 5266-5270 (2008). 67. T. Qunyi and Z. Ganwei, ' Rapid synthesis of a superabsorbent from a saponified starch and acrylonitrile/AMPS graft copolymers ', Carbohydrate Polymers, 62 (1), 74-79 (2005). 68. W. Tao, W. Xiaoqing, Y. Yi and H. Wenqiong, ' Preparation of bentonite–poly[(acrylic acid)-acrylamide] water superabsorbent by photopolymerization ', Polymer International, 55 (12), 1413-1419 (2006). 69. J. Z. Gao, D. L. Ma, Q. F. Lu, Y. Li, X. F. Li and W. Yang, ' Synthesis and Characterization of Montmorillonite-Graft-Acrylic Acid Superabsorbent by Using Glow-Discharge Electrolysis Plasma ', Plasma Chem. Plasma Process., 30 (6), 873-883 (2010). 70. J. Morales-Corona, J. A. Lopez-Barrera, A. Avila-Ortega, G. J. Cruz, M. G. Olayo, M. Ortega-Lopez, M. Vasquez-Ortega, H. Vazquez and R. Olayo, ' Luminescent Polydibenzothiophene Thin Film Obtained by Glow Discharge Method ', J. Appl. Polym. Sci., 123 (2), 1120-1124 (2012). 71. Z. H. Zhang, J. Dou, F. F. Yan, X. J. Zheng, X. L. Li and S. M. Fang, ' Plasma Polymerized Pyrrole Films for Biological Applications: Correlation Between Protein Adsorption Properties and Characteristics ', Plasma Process. Polym., 8 (10), 923-931 (2011). 72. J. Trieschmann and D. Hegemann, ' Plasma polymerization at different positions in an asymmetric ethylene discharge ', J. Phys. D-Appl. Phys., 44 (47)(2011). 73. H. Goktas, T. Gunes, B. Atalay, A. O. Er and I. Kaya, ' Plasma Copolymerization of Thiophene and Pyrrole ', Plasma Science, IEEE Transactions on, 39 (11), 2578-2579 (2011). 74. J. Friedrich, ' Mechanisms of Plasma Polymerization – Reviewed from a Chemical Point of View ', Plasma Process. Polym., 8 (9), 783-802 (2011). 75. C.-C. Chang, Y.-H. Chang, K.-C. Hwang, J.-H. Jou and A. C. M. Yang, ' One-step Fabrication of π-Conjugated Polymer Thin Films from Naphthalenes via Plasma Polymerization for Efficient Optoelectronic Devices: White Polymer Light-emitting Diodes ', Plasma Process. Polym., 8 (3), 215-223 (2011). 76. N. D. Boscher, P. Choquet, D. Duday, N. Kerbellec, J.-C. Lambrechts and R. Maurau, ' Luminescent lanthanide-based hybrid coatings deposited by atmospheric pressure plasma assisted chemical vapour deposition ', Journal of Materials Chemistry, 21 (47), 18959-18961 (2011). 77. J. Friedrich, R. Mix, uuml, G. hn, I. Retzko, Sch, ouml, A. nhals and W. Unger, ' Plasma-based introduction of monosort functional groups of different type and density onto polymer surfaces. Part 2: Pulsed plasma polymerization ', Composite Interfaces, 10 (2-3), 173-223 (2003). 78. T. Desmet, R. Morent, N. D. Geyter, C. Leys, E. Schacht and P. Dubruel, ' Nonthermal Plasma Technology as a Versatile Strategy for Polymeric Biomaterials Surface Modification: A Review ', Biomacromolecules, 10 (9), 2351-2378 (2009). 79. H. Yasuda and T. Hsu, ' Some aspects of plasma polymerization investigated by pulsed R.F. discharge ', Journal of Polymer Science: Polymer Chemistry Edition, 15 (1), 81-97 (1977). 80. I. Gancarz, J. Bryjak, G. Poźniak and W. Tylus, ' Plasma modified polymers as a support for enzyme immobilization II. Amines plasma ', European Polymer Journal, 39 (11), 2217-2224 (2003). 81. Z. H. Zhang, P. Liang, X. J. Zheng, D. L. Peng, F. F. Yan, R. Zhao and C. L. Feng, ' DNA immobilization/hybridization on plasma-polymerized pyrrole ', Biomacromolecules, 9 (6), 1613-1617 (2008). 82. J. Wang, K. G. Neoh and E. T. Kang, ' Comparative study of chemically synthesized and plasma polymerized pyrrole and thiophene thin films ', Thin Solid Films, 446 (2), 205-217 (2004). 83. K. Hosono, I. Matsubara, N. Murayama, W. Shin and N. Izu, ' Effects of discharge power on the structure and electrical properties of plasma polymerized polypyrrole films ', Materials Letters, 58 (7–8), 1371-1374 (2004). 84. I. Gancarz, G. Poźniak, M. Bryjak and W. Tylus, ' Modification of polysulfone membranes 5. Effect of n-butylamine and allylamine plasma ', European Polymer Journal, 38 (10), 1937-1946 (2002). 85. G. Poźniak, I. Gancarz, M. Bryjak and W. Tylus, ' N-butylamine plasma modifying ultrafiltration polysulfone membranes ', Desalination, 146 (1–3), 293-299 (2002). 86. A. Denizli, B. Salih and E. Pişkin, ' New sorbents for removal of heavy metal ions: diamine-glow-discharge treated polyhydroxyethylmethacrylate microspheres ', Journal of Chromatography A, 773 (1–2), 169-178 (1997). 87. J. Xu and K. K. Gleason, ' Conformal, amine-functionalized thin films by initiated chemical vapor deposition (iCVD) for hydrolytically stable microfluidic devices ', Chemistry of Materials, 22 (5), 1732-1738 (2010). 88. A. Hiratsuka, H. Muguruma, S. Sasaki, K. Ikebukuro and I. Karube, ' A glucose sensor with a plasma-polymerized thin film fabricated by dry processes ', Electroanalysis, 11 (15), 1098-1100 (1999). 89. K. Nakanishi, H. Muguruma and I. Karube, ' A novel method of immobilizing antibodies on a quartz crystal microbalance using plasma-polymerized films for immunosensors ', Anal. Chem., 68 (10), 1695-1700 (1996). 90. D. Mangindaan, W.-H. Kuo, C.-C. Chang, S.-L. Wang, H.-C. Liu and M.-J. Wang, ' Plasma polymerization of amine-containing thin films and the studies on the deposition kinetics ', Surface and Coatings Technology, 206 (6), 1299-1306 (2011). 91. A. Choukourov, H. Biederman, D. Slavinska, L. Hanley, A. Grinevich, H. Boldyryeva and A. Mackova, ' Mechanistic Studies of Plasma Polymerization of Allylamine ', The Journal of Physical Chemistry B, 109 (48), 23086-23095 (2005). 92. F. Fally, C. Doneux, J. Riga and J. J. Verbist, ' Quantification of the functional groups present at the surface of plasma polymers deposited from propylamine, allylamine, and propargylamine ', J. Appl. Polym. Sci., 56 (5), 597-614 (1995). 93. P. Hamerli, T. Weigel, T. Groth and D. Paul, ' Surface properties of and cell adhesion onto allylamine-plasma-coated polyethylenterephtalat membranes ', Biomaterials, 24 (22), 3989-3999 (2003). 94. X. Wang, J. Wang, Z. Yang, Y. Leng, H. Sun and N. Huang, ' Structural characterization and mechanical properties of functionalized pulsed-plasma polymerized allylamine film ', Surface and Coatings Technology, 204 (18–19), 3047-3052 (2010). 95. A. Abbas, D. Vercaigne-Marko, P. Supiot, B. Bocquet, C. Vivien and D. Guillochon, ' Covalent attachment of trypsin on plasma polymerized allylamine ', Colloids and Surfaces B: Biointerfaces, 73 (2), 315-324 (2009). 96. O. Kylian, J. Kousal, A. Artemenko, A. Choukourov, M. Petr, O. Polonskyi, D. Slavinska and H. Biederman, ' Deposition of amino-rich coatings by RF magnetron sputtering of Nylon: In-situ characterization of the deposition process ', Surface and Coatings Technology, 205, Supplement 2 (0), S558-S561 (2011). 97. Y. Akishev, M. Grushin, I. Kochetov, V. Karal'nik, A. Napartovich and N. Trushkin, ' Negative corona, glow and spark discharges in ambient air and transitions between them ', Plasma Sources Sci. Technol., 14 (2), S18-S25 (2005). 98. Y. S. Akishev, G. I. Aponin, M. E. Grushin, V. B. Karal'nik, M. V. Pan'kin, A. V. Petryakov and N. I. Trushkin, ' Alternating nonsteady gas-discharge modes in an atmospheric-pressure air flow blown through a point-plane gap ', Plasma Phys. Rep., 34 (4), 312-324 (2008). 99. P. Chabert, C. Lazzaroni and A. Rousseau, ' A model for the self-pulsing regime of microhollow cathode discharges ', Journal of Applied Physics, 108 (11)(2010). 100. C. Lazzaroni and P. Chabert, ' Discharge resistance and power dissipation in the self-pulsing regime of micro-hollow cathode discharges ', Plasma Sources Science and Technology, 20 (5), 055004 (2011). 101. P. Bruggeman, T. Verreycken, M. A. Gonzalez, J. L. Walsh, M. G. Kong, C. Leys and D. C. Schram, ' Optical emission spectroscopy as a diagnostic for plasmas in liquids: opportunities and pitfalls ', J. Phys. D-Appl. Phys., 43 (12)(2010). 102. P. Bruggeman, D. Schram, M. A. Gonzalez, R. Rego, M. G. Kong and C. Leys, ' Characterization of a direct dc-excited discharge in water by optical emission spectroscopy ', Plasma Sources Sci. Technol., 18 (2)(2009).
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/65004	-
dc.description.abstract	本研究包含在常壓下利用直流電源產生的微電漿系統進行診斷以及使用介電質放電系統應用至微小毛細管柱(管內徑為1mm至260μm)內與可撓式管材中進行聚烯丙胺薄膜之沉積與產物檢測。實驗的第一部分在常壓微電漿系統檢測部分主要包含電性檢測及光學檢測。而第二部分為聚烯丙胺薄膜之沉積包含製程的建立與在微小管材中做薄膜定性定量之探討，藉由此兩種不同之研究分別了解常壓下直流電源產生之微電漿系統各項操作參數改變對於放電特性之影響以及介電質放電系統對於管內薄膜沉積之品質與分佈的影響。第一部分中對於直流電源產生之微電漿放電特性及光學性質診斷發現，在不同的施加電壓下電漿系統會出現三種不同的放電型態，分別在操作電壓低於550V系統為「自我脈衝式放電」之型態；當操作電壓在550至650V時，電漿呈現「過渡狀態放電」以及操作電壓高於650V後則會轉變成「穩定放電」之型態。因此隨著施加電壓上升或系統串聯之鎮流電阻值下降可以觀察到電漿放電特性從自我脈衝放電轉變至穩定型放電；藉由簡易的電路學耦合微分方程式描述放電機制驗證實驗結果。本系統可藉由改變電極間距、操作電壓或鎮流電阻值，調整電漿欲達到之放電型態。從光學性質之診斷中了解系統中所包含之氣體離子與自由基種類，確保操作環境氣氛品質以及電漿生命週期，探討此系統對於高分子薄膜沉積及製程之可能性。而本實驗的第二部分主要利用介電質放電應用於管內徑1mm以及260μm之毛細管中並且能夠在管內徑為1mm、長1m之可撓式矽膠管中進行聚烯丙胺薄膜沉積。利用介電質放電產生具高反應性的自由基與分子，在低溫穩定操作環境下將常溫常壓下為液態的烯丙胺單體做為反應先驅物，藉由起泡器通以氬氣將反應先驅物送入電漿反應槽中產生反應，並在可撓式管壁中沉積薄膜。經由複式轉換紅外線光譜儀確立常壓微電漿系統有能力在短時間內於內徑為1mm之可撓式矽膠管中將烯丙胺單體發生聚合反應生成聚烯丙胺薄膜，表現出電漿高反應性與此系統應用於生醫材料各領域的前瞻性。藉由電漿操作條件對薄膜沉積實驗的影響，發現電漿處理時間從10增加至90min對於薄膜表面粗糙度與均勻性會有所改變；且在反應先驅物之高氣體流率50sccm下，此時滯留時間短有助於管內沉積之薄膜軸向分佈的均勻度。並藉由光電子能譜儀測定薄膜之元素組成以及鍵結結構以及電子顯微鏡觀察薄膜表面形態，證明此微電漿系統能夠在可撓式微型管材中做為高分子薄膜沉積的理想技術。	zh_TW
dc.description.abstract	Diagnostic of micro-discharges by a DC power source at atmospheric pressure and applications for plasma-polymerized allylamine film (PPA) onto inner surface of a flexible tubing by dielectric barrier discharges (DBDs) are studied. The micro-discharge characteristics are investigated by an oscilloscope and optical emission spectrometer. Process of PPA film by dielectric barrier discharges is established. Micro-plasmas are sustained in the tubing of 1 mm and 260 μm in diameter, respectively. The qualitative/quantitative analyses of PPA film are also predicted in the sub-millimeter tubing by analytic instruments. In dc micro-discharge system, the transition of micro-discharges is observed by modulating applied voltage. Three discharge modes are indentified that are ‘self-pulsing’, ‘transition’ and ‘stable’ discharge, respectively. The micro-discharge behaviors can be described by simple coupled differential equations and approached to experiment results. It is shown that the micro-discharge behaviors are controlled by the inter-electrode gap, applied voltage as well as ballast resistor. The activity species of micro-plasmas in the different feedstock and periodic light emission are monitored to realize chemistry and physical properties of plasmas by optical measurements. The PPA film deposition process by using DBDs is studied. In this process, allylamine is used as a precursor into micro-plasma reactor with a bubbler and PPA film deposition is performed in a high aspect ratio silicone tubing (1 m in long and 1 mm in inner diameter) by DBDs in argon. Chemical characteristics of deposited polymers are studied by ATR-FTIR. It is shown that this micro-plasma technology can be potentially utilized applications for biomaterials and surface coating. The effects of the operating conditions, namely treatment time and gas flow rate, on the roughness and uniformity of PPA film are confirmed. It is shown that PPA film quality and distribution of a 35 cm long silicone tubing in axis direction is controlled by the resident time of precursor in the tubing. The PPA film chemical composition is examined by XPS and the morphology of deposited PPA film is investigated by SEM.	en
dc.description.provenance	Made available in DSpace on 2021-06-16T23:14:33Z (GMT). No. of bitstreams: 1 ntu-101-R99524079-1.pdf: 9706784 bytes, checksum: 9c389945a5929c3c0f348781283aa7f6 (MD5) Previous issue date: 2012	en
dc.description.tableofcontents	誌謝 I 中文摘要 III 英文摘要 V 目錄 VII 圖目錄 XI 表目錄 XX 第1章緒論 1 1.1 前言 1 1.2 研究動機 2 1.3 論文總覽 2 第2章文獻回顧 5 2.1 微電漿系統 5 2.1.1 微電漿之種類 5 2.1.2 微電漿放電與物理特性 13 2.1.3 微電漿技術之應用 17 2.2 毛細管及可撓式管材之微電漿系統 22 2.2.1 內管壁表面電漿沉積技術 28 2.3 高分子聚合反應 33 2.3.1 化學物質引發之高分子聚合反應 33 2.3.2 光聚合反應法 33 2.3.3 輻射誘導聚合反應法 34 2.3.4 電漿聚合反應法 34 2.3.5 脈衝式電漿之高分子聚合反應 36 2.4 聚烯丙胺薄膜 40 2.4.1 胺基高分子薄膜之特色 40 2.4.2 以電漿系統進行胺基高分子薄膜沉積 41 2.4.3 聚烯丙胺薄膜之檢測方法 44 第3章實驗設備與架構 49 3.1 常壓微電漿系統 52 3.1.1 以矽玻璃為基底的鋁電極之製程 52 3.1.2 微電漿系統之性質檢測 53 3.2 常壓介電質放電系統 55 3.2.1 薄膜分析檢測儀器 56 第4章實驗結果 63 4.1 常壓微電漿之放電特性 63 4.1.1 不同操作電壓下之微電漿型態 63 4.1.2 微電漿放電之電流電壓波形 63 4.1.3 微電漿放電之特徵曲線 66 4.1.4 數值模擬之微電漿放電特性 73 4.1.5 放射光譜之波峰鑑定與其光學檢測 78 4.2 系統之外部元件對電漿性質的影響 82 4.2.1 自我脈衝頻率與操作電壓之關係 82 4.2.2 電極間距對微電漿放電之影響 85 4.2.3 氣體流率對微電漿放電之影響 89 4.2.4 微電漿系統電子密度之檢測 90 4.2.5 微電漿不同放電型態對消耗功率之影響 92 4.3 利用介電質放電進行聚烯丙胺薄膜沉積 94 4.3.1 毛細管中進行介電質放電之研究 94 4.3.2 微米管材中進行介電質放電之研究 94 4.3.3 高長寬比之可撓式微電漿系統 95 4.3.4 介電質放電系統之電性分析 95 4.3.5 介電質放電系統之光譜分析 96 4.3.6 薄膜之材料結構分析 102 4.3.7 薄膜之組成與化學形態分析 109 4.3.8 薄膜之表面顯微形態分析 114 第5章結論與未來展望 119 第6章參考文獻 121 附錄A 135 附錄B 137
dc.language.iso	zh-TW
dc.subject	常壓微電漿	zh_TW
dc.subject	自我脈衝式放電	zh_TW
dc.subject	介電質放電系統	zh_TW
dc.subject	聚烯丙胺薄膜	zh_TW
dc.subject	高分子聚合反應	zh_TW
dc.subject	plasma-polymerized allylamine film	en
dc.subject	atmospheric pressure dc micro-discharges	en
dc.subject	self-pulsing discharges	en
dc.subject	polymerization by plasmas	en
dc.subject	dielectric barrier discharges	en
dc.title	常壓微電漿系統之診斷及進行高分子薄膜沉積之製程研究	zh_TW
dc.title	Diagnostic Study of Micro-discharge at Atmospheric Pressure and its Applications of Plasma-polymerized Film Deposition.	en
dc.type	Thesis
dc.date.schoolyear	100-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳建彰,盧彥文,廖英志
dc.subject.keyword	常壓微電漿,自我脈衝式放電,介電質放電系統,聚烯丙胺薄膜,高分子聚合反應,	zh_TW
dc.subject.keyword	atmospheric pressure dc micro-discharges,self-pulsing discharges,dielectric barrier discharges,plasma-polymerized allylamine film,polymerization by plasmas,	en
dc.relation.page	140
dc.rights.note	有償授權
dc.date.accepted	2012-08-03
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	化學工程學研究所	zh_TW
顯示於系所單位：	化學工程學系

文件中的檔案：

檔案	大小	格式
ntu-101-1.pdf 未授權公開取用	9.48 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。