常壓介電質放電噴射電漿改質聚苯胺-石墨烯-殼聚醣軟性超級電容及紙基超級電容製程開發

Jui-Chen Hsin; 辛睿宸

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/78359

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	陳建彰(Jian-Zhang Chen)
dc.contributor.author	Jui-Chen Hsin	en
dc.contributor.author	辛睿宸	zh_TW
dc.date.accessioned	2021-07-11T14:52:57Z	-
dc.date.available	2023-07-30
dc.date.copyright	2020-08-03
dc.date.issued	2020
dc.date.submitted	2020-07-24
dc.identifier.citation	[1] A. A. Sneha Lele. (2018). Electrical Engineering Computer Science Supercapacitors: A Comparative Analysis [Online]. Available: https://www.exponent.com/knowledge/alerts/2018/02/supercapacitors/?pageSize=NaN pageNum=0 loadAllByPageSize=true. [2] E. Frackowiak, 'Carbon materials for supercapacitor application,' Physical chemistry chemical physics, vol. 9, no. 15, pp. 1774-1785, 2007. [3] Y. Zhu et al., 'Carbon-based supercapacitors produced by activation of graphene,' science, vol. 332, no. 6037, pp. 1537-1541, 2011. [4] L. L. Zhang and X. Zhao, 'Carbon-based materials as supercapacitor electrodes,' Chemical Society Reviews, vol. 38, no. 9, pp. 2520-2531, 2009. [5] M. Zhi, C. Xiang, J. Li, M. Li, and N. Wu, 'Nanostructured carbon–metal oxide composite electrodes for supercapacitors: a review,' Nanoscale, vol. 5, no. 1, pp. 72-88, 2013. [6] X. Lang, A. Hirata, T. Fujita, and M. Chen, 'Nanoporous metal/oxide hybrid electrodes for electrochemical supercapacitors,' Nature nanotechnology, vol. 6, no. 4, pp. 232-236, 2011. [7] C. Lokhande, D. Dubal, and O.-S. Joo, 'Metal oxide thin film based supercapacitors,' Current Applied Physics, vol. 11, no. 3, pp. 255-270, 2011. [8] A. Eftekhari, L. Li, and Y. Yang, 'Polyaniline supercapacitors,' Journal of Power Sources, vol. 347, pp. 86-107, 2017. [9] K. Zhang, L. L. Zhang, X. Zhao, and J. Wu, 'Graphene/polyaniline nanofiber composites as supercapacitor electrodes,' Chemistry of Materials, vol. 22, no. 4, pp. 1392-1401, 2010. [10] H. Wang, Q. Hao, X. Yang, L. Lu, and X. Wang, 'Graphene oxide doped polyaniline for supercapacitors,' Electrochemistry Communications, vol. 11, no. 6, pp. 1158-1161, 2009. [11] R. Kötz and M. Carlen, 'Principles and applications of electrochemical capacitors,' Electrochimica acta, vol. 45, no. 15-16, pp. 2483-2498, 2000. [12] S. Pay and Y. Baghzouz, 'Effectiveness of battery-supercapacitor combination in electric vehicles,' in 2003 IEEE Bologna Power Tech Conference Proceedings, 2003, vol. 3: IEEE, p. 6 pp. Vol. 3. [13] B. E. Conway, 'Transition from “supercapacitor” to “battery” behavior in electrochemical energy storage,' Journal of the Electrochemical Society, vol. 138, no. 6, p. 1539, 1991. [14] A. G. Pandolfo and A. F. Hollenkamp, 'Carbon properties and their role in supercapacitors,' Journal of power sources, vol. 157, no. 1, pp. 11-27, 2006. [15] P. Simon, Y. Gogotsi, and B. Dunn, 'Where do batteries end and supercapacitors begin?,' Science, vol. 343, no. 6176, pp. 1210-1211, 2014. [16] D. P. Dubal, O. Ayyad, V. Ruiz, and P. Gomez-Romero, 'Hybrid energy storage: the merging of battery and supercapacitor chemistries,' Chemical Society Reviews, vol. 44, no. 7, pp. 1777-1790, 2015. [17] H. Gao and K. Lian, 'Proton-conducting polymer electrolytes and their applications in solid supercapacitors: a review,' RSC advances, vol. 4, no. 62, pp. 33091-33113, 2014. [18] Q. Lu et al., 'Supercapacitor electrodes with high‐energy and power densities prepared from monolithic NiO/Ni nanocomposites,' Angewandte Chemie International Edition, vol. 50, no. 30, pp. 6847-6850, 2011. [19] A. Balducci et al., 'High temperature carbon–carbon supercapacitor using ionic liquid as electrolyte,' Journal of power sources, vol. 165, no. 2, pp. 922-927, 2007. [20] F. Béguin, V. Presser, A. Balducci, and E. Frackowiak, 'Carbons and electrolytes for advanced supercapacitors,' Advanced materials, vol. 26, no. 14, pp. 2219-2251, 2014. [21] G. Wang, L. Zhang, and J. Zhang, 'A review of electrode materials for electrochemical supercapacitors,' Chemical Society Reviews, vol. 41, no. 2, pp. 797-828, 2012. [22] A. Borenstein, O. Hanna, R. Attias, S. Luski, T. Brousse, and D. Aurbach, 'Carbon-based composite materials for supercapacitor electrodes: a review,' Journal of Materials Chemistry A, vol. 5, no. 25, pp. 12653-12672, 2017. [23] M. Vangari, T. Pryor, and L. Jiang, 'Supercapacitors: review of materials and fabrication methods,' Journal of Energy Engineering, vol. 139, no. 2, pp. 72-79, 2013. [24] A. González, E. Goikolea, J. A. Barrena, and R. Mysyk, 'Review on supercapacitors: technologies and materials,' Renewable and Sustainable Energy Reviews, vol. 58, pp. 1189-1206, 2016. [25] F. Belhachemi, S. Rael, and B. Davat, 'A physical based model of power electric double-layer supercapacitors,' in Conference Record of the 2000 IEEE Industry Applications Conference. Thirty-Fifth IAS Annual Meeting and World Conference on Industrial Applications of Electrical Energy (Cat. No. 00CH37129), 2000, vol. 5: IEEE, pp. 3069-3076. [26] M. Endo, T. Takeda, Y. Kim, K. Koshiba, and K. Ishii, 'High power electric double layer capacitor (EDLC's); from operating principle to pore size control in advanced activated carbons,' Carbon letters, vol. 1, no. 3_4, pp. 117-128, 2001. [27] J. R. Miller and P. Simon, 'Electrochemical capacitors for energy management,' science, vol. 321, no. 5889, pp. 651-652, 2008. [28] J. P. Zheng, J. Huang, and T. Jow, 'The limitations of energy density for electrochemical capacitors,' Journal of the Electrochemical Society, vol. 144, no. 6, p. 2026, 1997. [29] B. E. Conway, Electrochemical supercapacitors: scientific fundamentals and technological applications. Springer Science Business Media, 2013. [30] S. Trasatti and G. Buzzanca, 'Ruthenium dioxide: a new interesting electrode material. Solid state structure and electrochemical behaviour,' Journal of Electroanalytical Chemistry and Interfacial Electrochemistry, vol. 29, no. 2, pp. A1-A5, 1971. [31] X.-h. Xia et al., 'Freestanding Co3O4 nanowire array for high performance supercapacitors,' Rsc Advances, vol. 2, no. 5, pp. 1835-1841, 2012. [32] X.-h. Xia, J.-p. Tu, Y.-j. Mai, X.-l. Wang, C.-d. Gu, and X.-b. Zhao, 'Self-supported hydrothermal synthesized hollow Co3O4 nanowire arrays with high supercapacitor capacitance,' Journal of Materials Chemistry, vol. 21, no. 25, pp. 9319-9325, 2011. [33] L. Demarconnay, E. Raymundo-Piñero, and F. Béguin, 'Adjustment of electrodes potential window in an asymmetric carbon/MnO2 supercapacitor,' Journal of Power Sources, vol. 196, no. 1, pp. 580-586, 2011. [34] S. Chen, J. Zhu, X. Wu, Q. Han, and X. Wang, 'Graphene oxide− MnO2 nanocomposites for supercapacitors,' ACS nano, vol. 4, no. 5, pp. 2822-2830, 2010. [35] X. Lu et al., 'H‐TiO2@ MnO2//H‐TiO2@ C core–shell nanowires for high performance and flexible asymmetric supercapacitors,' Advanced Materials, vol. 25, no. 2, pp. 267-272, 2013. [36] X. Lu et al., 'Hydrogenated TiO2 nanotube arrays for supercapacitors,' Nano letters, vol. 12, no. 3, pp. 1690-1696, 2012. [37] Q. Wang, L. Jiao, H. Du, Y. Wang, and H. Yuan, 'Fe3O4 nanoparticles grown on graphene as advanced electrode materials for supercapacitors,' Journal of Power Sources, vol. 245, pp. 101-106, 2014. [38] X. Du, C. Wang, M. Chen, Y. Jiao, and J. Wang, 'Electrochemical performances of nanoparticle Fe3O4/activated carbon supercapacitor using KOH electrolyte solution,' The Journal of Physical Chemistry C, vol. 113, no. 6, pp. 2643-2646, 2009. [39] L. Wang et al., 'Flexible solid-state supercapacitor based on a metal–organic framework interwoven by electrochemically-deposited PANI,' Journal of the American Chemical Society, vol. 137, no. 15, pp. 4920-4923, 2015. [40] V. Gupta and N. Miura, 'Polyaniline/single-wall carbon nanotube (PANI/SWCNT) composites for high performance supercapacitors,' Electrochimica acta, vol. 52, no. 4, pp. 1721-1726, 2006. [41] V. Augustyn, P. Simon, and B. Dunn, 'Pseudocapacitive oxide materials for high-rate electrochemical energy storage,' Energy Environmental Science, vol. 7, no. 5, pp. 1597-1614, 2014. [42] R. S. Kate, S. A. Khalate, and R. J. Deokate, 'Overview of nanostructured metal oxides and pure nickel oxide (NiO) electrodes for supercapacitors: A review,' Journal of Alloys and Compounds, vol. 734, pp. 89-111, 2018. [43] S. Faraji and F. N. Ani, 'Microwave-assisted synthesis of metal oxide/hydroxide composite electrodes for high power supercapacitors–a review,' Journal of Power Sources, vol. 263, pp. 338-360, 2014. [44] C. R. Martin, 'Template synthesis of electronically conductive polymer nanostructures,' Accounts of chemical research, vol. 28, no. 2, pp. 61-68, 1995. [45] E. Genies, A. Boyle, M. Lapkowski, and C. Tsintavis, 'Polyaniline: a historical survey,' Synthetic metals, vol. 36, no. 2, pp. 139-182, 1990. [46] B. Conway and W. Pell, 'Double-layer and pseudocapacitance types of electrochemical capacitors and their applications to the development of hybrid devices,' Journal of Solid State Electrochemistry, vol. 7, no. 9, pp. 637-644, 2003. [47] L. L. Zhang, R. Zhou, and X. Zhao, 'Graphene-based materials as supercapacitor electrodes,' Journal of Materials Chemistry, vol. 20, no. 29, pp. 5983-5992, 2010. [48] C. Zhong, Y. Deng, W. Hu, J. Qiao, L. Zhang, and J. Zhang, 'A review of electrolyte materials and compositions for electrochemical supercapacitors,' Chemical Society Reviews, vol. 44, no. 21, pp. 7484-7539, 2015. [49] E. Frackowiak, 'Supercapacitors based on carbon materials and ionic liquids,' Journal of the Brazilian Chemical Society, vol. 17, no. 6, pp. 1074-1082, 2006. [50] I. Langmuir, 'Oscillations in ionized gases,' Proceedings of the National Academy of Sciences of the United States of America, vol. 14, no. 8, p. 627, 1928. [51] M. A. Lieberman and A. J. Lichtenberg, Principles of plasma discharges and materials processing. John Wiley Sons, 2005. [52] F. B. Srl. (2020). Plasma treatment at atmospheric pressure conditions [Online]. Available: https://www.ferben.com/technology/atmospheric-plasma-treatment.kl. [53] Y. P. Raizer, 'Gas discharge physics,' 1991. [54] A. Schutze, J. Y. Jeong, S. E. Babayan, J. Park, G. S. Selwyn, and R. F. Hicks, 'The atmospheric-pressure plasma jet: a review and comparison to other plasma sources,' IEEE transactions on plasma science, vol. 26, no. 6, pp. 1685-1694, 1998. [55] M. Busquet, 'Mixed model: Non-local-thermodynamic equilibrium, non-coronal-equilibrium simple ionization model for laser-created plasmas,' Physical Review A, vol. 25, no. 4, p. 2302, 1982. [56] T. Fujimoto and R. McWhirter, 'Validity criteria for local thermodynamic equilibrium in plasma spectroscopy,' Physical Review A, vol. 42, no. 11, p. 6588, 1990. [57] K. Tachibana, 'Current status of microplasma research,' IEEJ Transactions on Electrical and Electronic Engineering, vol. 1, no. 2, pp. 145-155, 2006. [58] B. Eliasson and U. Kogelschatz, 'Nonequilibrium volume plasma chemical processing,' IEEE transactions on plasma science, vol. 19, no. 6, pp. 1063-1077, 1991. [59] P. D. Hong Xiao. (2015). Chapter 7. Plasma Basic. [Online]. Available: http://apachepersonal.miun.se/~gorthu/ch07.pdf. [60] G. Selwyn, H. Herrmann, J. Park, and I. Henins, 'Materials Processing Using an Atmospheric Pressure, RF‐Generated Plasma Source,' Contributions to Plasma Physics, vol. 41, no. 6, pp. 610-619, 2001. [61] H. W. Herrmann, I. Henins, J. Park, and G. J. P. o. p. Selwyn, 'Decontamination of chemical and biological warfare (CBW) agents using an atmospheric pressure plasma jet (APPJ),' vol. 6, no. 5, pp. 2284-2289, 1999. [62] M. Iwasaki et al., 'Nonequilibrium atmospheric pressure plasma with ultrahigh electron density and high performance for glass surface cleaning,' vol. 92, no. 8, p. 081503, 2008. [63] M. Kim et al., 'Surface modification for hydrophilic property of stainless steel treated by atmospheric-pressure plasma jet,' vol. 171, no. 1-3, pp. 312-316, 2003. [64] J. Jeong et al., 'Etching materials with an atmospheric-pressure plasma jet,' vol. 7, no. 3, p. 282, 1998. [65] S. Babayan et al., 'Deposition of silicon dioxide films with an atmospheric-pressure plasma jet,' vol. 7, no. 3, p. 286, 1998. [66] G. Daeschlein et al., 'Skin decontamination by low-temperature atmospheric pressure plasma jet and dielectric barrier discharge plasma,' vol. 81, no. 3, pp. 177-183, 2012. [67] J. M. Ranish, K. K. Singh, and B. Adams, 'Substrate processing chamber with dielectric barrier discharge lamp assembly,' ed: Google Patents, 2011. [68] M. V. Naseh, A. A. Khodadadi, Y. Mortazavi, F. Pourfayaz, O. Alizadeh, and M. J. C. Maghrebi, 'Fast and clean functionalization of carbon nanotubes by dielectric barrier discharge plasma in air compared to acid treatment,' vol. 48, no. 5, pp. 1369-1379, 2010. [69] H.-K. Seo, C. M. Elliott, H.-S. J. A. a. m. Shin, and interfaces, 'Mesoporous TiO2 films fabricated using atmospheric pressure dielectric barrier discharge jet,' vol. 2, no. 12, pp. 3397-3400, 2010. [70] W. Xu and X. J. E. P. J. Liu, 'Surface modification of polyester fabric by corona discharge irradiation,' vol. 39, no. 1, pp. 199-202, 2003. [71] J. Trelles, C. Chazelas, A. Vardelle, and J. J. J. o. t. s. t. Heberlein, 'Arc plasma torch modeling,' vol. 18, no. 5-6, p. 728, 2009. [72] J.-S. J. S. Chang and T. o. A. Materials, 'Recent development of plasma pollution control technology: a critical review,' vol. 2, no. 3-4, pp. 571-576, 2001. [73] N. J. C. S. Venkatramani, 'Industrial plasma torches and applications,' pp. 254-262, 2002. [74] K. S. Novoselov et al., 'Electric field effect in atomically thin carbon films,' science, vol. 306, no. 5696, pp. 666-669, 2004. [75] F. Schedin et al., 'Detection of individual gas molecules adsorbed on graphene,' Nature materials, vol. 6, no. 9, pp. 652-655, 2007. [76] F. Schwierz, 'Graphene transistors,' Nature nanotechnology, vol. 5, no. 7, p. 487, 2010. [77] S.-J. Han, A. V. Garcia, S. Oida, K. A. Jenkins, and W. Haensch, 'Graphene radio frequency receiver integrated circuit,' Nature communications, vol. 5, no. 1, pp. 1-6, 2014. [78] Q. Liang, X. Yao, W. Wang, Y. Liu, and C. P. Wong, 'A three-dimensional vertically aligned functionalized multilayer graphene architecture: an approach for graphene-based thermal interfacial materials,' ACS nano, vol. 5, no. 3, pp. 2392-2401, 2011. [79] Z. Pan, H. Gu, M.-T. Wu, Y. Li, and Y. Chen, 'Graphene-based functional materials for organic solar cells,' Optical Materials Express, vol. 2, no. 6, pp. 814-824, 2012. [80] Y. B. Tan and J.-M. Lee, 'Graphene for supercapacitor applications,' Journal of Materials Chemistry A, vol. 1, no. 47, pp. 14814-14843, 2013. [81] C. Lee, X. Wei, J. W. Kysar, and J. Hone, 'Measurement of the elastic properties and intrinsic strength of monolayer graphene,' science, vol. 321, no. 5887, pp. 385-388, 2008. [82] A. Ambrosi, C. K. Chua, A. Bonanni, and M. Pumera, 'Electrochemistry of graphene and related materials,' Chemical reviews, vol. 114, no. 14, pp. 7150-7188, 2014. [83] V. K. Das, Z. B. Shifrina, and L. M. Bronstein, 'Graphene and graphene-like materials in biomass conversion: paving the way to the future,' Journal of Materials Chemistry A, vol. 5, no. 48, pp. 25131-25143, 2017. [84] M. Yi and Z. Shen, 'A review on mechanical exfoliation for the scalable production of graphene,' Journal of Materials Chemistry A, vol. 3, no. 22, pp. 11700-11715, 2015. [85] S. Bae et al., 'Roll-to-roll production of 30-inch graphene films for transparent electrodes,' Nature nanotechnology, vol. 5, no. 8, p. 574, 2010. [86] X. Chen, L. Zhang, and S. Chen, 'Large area CVD growth of graphene,' Synthetic Metals, vol. 210, pp. 95-108, 2015. [87] H.-M. Ju, S. H. Huh, S.-H. Choi, and H.-L. Lee, 'Structures of thermally and chemically reduced graphene,' Materials Letters, vol. 64, no. 3, pp. 357-360, 2010. [88] M. Hirata, T. Gotou, S. Horiuchi, M. Fujiwara, and M. Ohba, 'Thin-film particles of graphite oxide 1:: High-yield synthesis and flexibility of the particles,' Carbon, vol. 42, no. 14, pp. 2929-2937, 2004. [89] H. Bai, C. Li, and G. Shi, 'Functional composite materials based on chemically converted graphene,' Advanced Materials, vol. 23, no. 9, pp. 1089-1115, 2011. [90] P. W. Sutter, J.-I. Flege, and E. A. Sutter, 'Epitaxial graphene on ruthenium,' Nature materials, vol. 7, no. 5, pp. 406-411, 2008. [91] Z.-Y. Juang et al., 'Synthesis of graphene on silicon carbide substrates at low temperature,' Carbon, vol. 47, no. 8, pp. 2026-2031, 2009. [92] J. Yan et al., 'Preparation of graphene nanosheet/carbon nanotube/polyaniline composite as electrode material for supercapacitors,' vol. 195, no. 9, pp. 3041-3045, 2010. [93] A. Mirmohseni and A. J. S. m. Oladegaragoze, 'Anti-corrosive properties of polyaniline coating on iron,' vol. 114, no. 2, pp. 105-108, 2000. [94] A. Andreatta, Y. Cao, J. C. Chiang, A. J. Heeger, and P. J. S. M. Smith, 'Electrically-conductive fibers of polyaniline spun from solutions in concentrated sulfuric acid,' vol. 26, no. 4, pp. 383-389, 1988. [95] R. J. Young and P. A. Lovell, Introduction to polymers. CRC press, 2011. [96] S. C. Yang, 'Conducting polymer as electrochromic material: polyaniline,' in Large-Area Chromogenics: Materials and Devices for Transmittance Control, 1990, vol. 10304: International Society for Optics and Photonics, p. 103040M. [97] S. Bhandari, 'Polyaniline: Structure and Properties Relationship,' in Polyaniline Blends, Composites, and Nanocomposites: Elsevier, 2018, pp. 23-60. [98] N. Abu-Thabit, Y. Umar, E. Ratemi, A. Ahmad, and F. J. S. Ahmad Abuilaiwi, 'A flexible optical pH sensor based on polysulfone membranes coated with pH-responsive polyaniline nanofibers,' vol. 16, no. 7, p. 986, 2016. [99] M. H. Naveen, N. G. Gurudatt, and Y.-B. J. A. m. t. Shim, 'Applications of conducting polymer composites to electrochemical sensors: a review,' vol. 9, pp. 419-433, 2017. [100] D. Merck KGaA, Germany. (2020). Chitosan [Online]. Available: https://www.sigmaaldrich.com/catalog/substance/chitosan12345901276411?lang=en region=TW. [101] J. Chase, N. Wenner, P. Ross, and M. Todd, 'Deacetylation and crosslinking of chitin and chitosan in fungal materials and their composites for tunable properties,' ed: Google Patents, 2019. [102] L. Tang, Z. Yang, F. Duan, and M. Chen, 'Fabrication of graphene sheets/polyaniline nanofibers composite for enhanced supercapacitor properties,' Colloids and Surfaces A: Physicochemical and Engineering Aspects, vol. 520, pp. 184-192, 2017. [103] X. Hong, B. Zhang, E. Murphy, J. Zou, and F. Kim, 'Three-dimensional reduced graphene oxide/polyaniline nanocomposite film prepared by diffusion driven layer-by-layer assembly for high-performance supercapacitors,' Journal of Power Sources, vol. 343, pp. 60-66, 2017. [104] J. Zhang, J. Jiang, H. Li, and X. Zhao, 'A high-performance asymmetric supercapacitor fabricated with graphene-based electrodes,' Energy Environmental Science, vol. 4, no. 10, pp. 4009-4015, 2011. [105] J. Luo, Q. Ma, H. Gu, Y. Zheng, and X. Liu, 'Three-dimensional graphene-polyaniline hybrid hollow spheres by layer-by-layer assembly for application in supercapacitor,' Electrochimica Acta, vol. 173, pp. 184-192, 2015. [106] C. Yang et al., 'Rational design of sandwiched polyaniline nanotube/layered graphene/polyaniline nanotube papers for high-volumetric supercapacitors,' Chemical Engineering Journal, vol. 309, pp. 89-97, 2017. [107] W. Tang et al., 'Facile synthesis of 3D reduced graphene oxide and its polyaniline composite for super capacitor application,' Synthetic Metals, vol. 202, pp. 140-146, 2015. [108] L. Wang et al., 'Hierarchical nanocomposites of polyaniline nanowire arrays on reduced graphene oxide sheets for supercapacitors,' Scientific reports, vol. 3, p. 3568, 2013. [109] M. Zhong et al., 'Effect of reduced graphene oxide on the properties of an activated carbon cloth/polyaniline flexible electrode for supercapacitor application,' Journal of power sources, vol. 217, pp. 6-12, 2012. [110] K. Gopalakrishnan, S. Sultan, A. Govindaraj, and C. Rao, 'Supercapacitors based on composites of PANI with nanosheets of nitrogen-doped RGO, BC1. 5N, MoS2 and WS2,' Nano Energy, vol. 12, pp. 52-58, 2015. [111] C.-C. Hsu and Y.-J. Yang, 'The increase of the jet size of an atmospheric-pressure plasma jet by ambient air control,' IEEE transactions on plasma science, vol. 38, no. 3, pp. 496-499, 2010. [112] A. R. Hsu et al., 'Scan-mode atmospheric-pressure plasma jet processed reduced graphene oxides for quasi-solid-state gel-electrolyte supercapacitors,' Coatings, vol. 8, no. 2, p. 52, 2018. [113] L. Dickens, 'Pictures on walls? Producing, pricing and collecting the street art screen print,' City, vol. 14, no. 1-2, pp. 63-81, 2010. [114] C.-F. Du, Q. Liang, Y. Luo, Y. Zheng, and Q. Yan, 'Recent advances in printable secondary batteries,' Journal of Materials Chemistry A, vol. 5, no. 43, pp. 22442-22458, 2017. [115] H. A. O. Hill, I. J. Higgins, J. M. McCann, and G. Davis, 'Strip electrode with screen printing,' ed: Google Patents, 1998. [116] J. Liang, K. Tong, and Q. Pei, 'A water‐based silver‐nanowire screen‐print ink for the fabrication of stretchable conductors and wearable thin‐film transistors,' Advanced Materials, vol. 28, no. 28, pp. 5986-5996, 2016. [117] J. I. Goldstein, D. E. Newbury, J. R. Michael, N. W. Ritchie, J. H. J. Scott, and D. C. Joy, Scanning electron microscopy and X-ray microanalysis. Springer, 2017. [118] H. Seiler, 'Secondary electron emission in the scanning electron microscope,' Journal of Applied Physics, vol. 54, no. 11, pp. R1-R18, 1983. [119] B. Inkson, 'Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) for materials characterization,' in Materials characterization using nondestructive evaluation (NDE) methods: Elsevier, 2016, pp. 17-43. [120] N. Erdman, D. C. Bell, and R. Reichelt, 'Scanning Electron Microscopy,' in Springer Handbook of Microscopy, P. W. Hawkes and J. C. H. Spence, Eds. Cham: Springer International Publishing, 2019, pp. 2-2. [121] M. a. M. Science. (2019). Scanning Electron Microscope (SEM) [Online]. Available: https://metallurgyandmaterialscience.com/scanning-electron-microscope/. [122] C. Aragón and J. A. Aguilera, 'Characterization of laser induced plasmas by optical emission spectroscopy: A review of experiments and methods,' Spectrochimica Acta Part B: Atomic Spectroscopy, vol. 63, no. 9, pp. 893-916, 2008. [123] J. Coburn and M. Chen, 'Optical emission spectroscopy of reactive plasmas: A method for correlating emission intensities to reactive particle density,' Journal of applied physics, vol. 51, no. 6, pp. 3134-3136, 1980. [124] P. M. O. Willy Sanders. (2017). What is Optical Emission Spectroscopy (OES)? [Online]. Available: https://hha.hitachi-hightech.com/ko/blogs-events/blogs/2017/10/25/optical-emission-spectroscopy-(oes)/. [125] R. J. Good, 'Contact angle, wetting, and adhesion: a critical review,' Journal of adhesion science and technology, vol. 6, no. 12, pp. 1269-1302, 1992. [126] P. Coatings. (2016). Surface Energy [Online]. Available: http://www.ptfecoatings.com/technology/surface-energy.php. [127] W. S. Bai Shaoxian. (2019). Vapor-condensed gas lubrication of face seals [Online]. Available: https://www.sciencedirect.com/topics/engineering/young-equation. [128] L. Segal, J. Creely, A. Martin Jr, and C. Conrad, 'An empirical method for estimating the degree of crystallinity of native cellulose using the X-ray diffractometer,' Textile research journal, vol. 29, no. 10, pp. 786-794, 1959. [129] R. A. Spurr and H. Myers, 'Quantitative analysis of anatase-rutile mixtures with an X-ray diffractometer,' Analytical chemistry, vol. 29, no. 5, pp. 760-762, 1957. [130] X-ray Diffraction [Online]. Available: http://pruffle.mit.edu/atomiccontrol/education/xray/xray_diff.php#xrays. [131] A. Authier, 'Dynamical theory of X‐ray diffraction,' International Tables for Crystallography, pp. 626-646, 2006. [132] S. Nasir, M. Z. Hussein, Z. Zainal, N. A. Yusof, S. A. M. Zobir, and I. M. Alibe, 'Potential valorization of by-product materials from oil palm: A review of alternative and sustainable carbon sources for carbon-based nanomaterials synthesis,' BioResources, vol. 14, no. 1, pp. 2352-2388, 2019. [133] D. A. Long and D. Long, Raman spectroscopy. McGraw-Hill New York, 1977. [134] J. R. Ferraro, Introductory raman spectroscopy. Elsevier, 2003. [135] D. D. Bhanot. (2015). What are the differences between Raman and IR Spectroscopy? [Online]. Available: https://lab-training.com/2015/06/26/what-are-the-differences-between-raman-and-ir-spectroscopy/. [136] M. J. Baker, C. S. Hughes, and K. A. Hollywood, Biophotonics: Vibrational Spectroscopic Diagnostics. Morgan Claypool Publishers, 2016. [137] M. Chen et al., 'X-ray photoelectron spectroscopy and auger electron spectroscopy studies of Al-doped ZnO films,' Applied Surface Science, vol. 158, no. 1-2, pp. 134-140, 2000. [138] D. Frost, A. Ishitani, and C. McDowell, 'X-ray photoelectron spectroscopy of copper compounds,' Molecular Physics, vol. 24, no. 4, pp. 861-877, 1972. [139] R. T. Haasch, 'X-ray photoelectron spectroscopy (XPS) and auger electron spectroscopy (AES),' in Practical Materials Characterization: Springer, 2014, pp. 93-132. [140] A. Thompson, 'Electrochemical potential spectroscopy: a new electrochemical measurement,' Journal of The Electrochemical Society, vol. 126, no. 4, p. 608, 1979. [141] B. J. Birth and I. W. Burns, 'Electrochemical measurement cell,' ed: Google Patents, 1990. [142] D. Graham. (2020). What Is Cyclic Voltammetry? [Online]. Available: https://sop4cv.com/chapters/WhatIsCyclicVoltammetry.html. [143] H. Borchert, 'Cyclic Voltammetry,' in Solar Cells Based on Colloidal Nanocrystals: Springer, 2014, pp. 111-117. [144] G. S. Gund et al., 'Low-cost flexible supercapacitors with high-energy density based on nanostructured MnO 2 and Fe 2 O 3 thin films directly fabricated onto stainless steel,' Scientific reports, vol. 5, p. 12454, 2015. [145] B. K. Kim, S. Sy, A. Yu, and J. Zhang, 'Electrochemical supercapacitors for energy storage and conversion,' Handbook of Clean Energy Systems, pp. 1-25, 2015. [146] R. Karthik et al., 'A facile graphene oxide based sensor for electrochemical detection of prostate anti-cancer (anti-testosterone) drug flutamide in biological samples,' RSC advances, vol. 7, no. 41, pp. 25702-25709, 2017. [147] G. Verhoeven, 'The reflection of two fields: electromagnetic radiation and its role in (aerial) imaging,' AARGNEWS, vol. 55, pp. 13-18, 2017. [148] H.-H. Chien et al., 'Improved performance of polyaniline/reduced-graphene-oxide supercapacitor using atmospheric-pressure-plasma-jet surface treatment of carbon cloth,' Electrochimica Acta, vol. 260, pp. 391-399, 2018. [149] A. Thakur, S. Kumar, and V. Rangra, 'Synthesis of reduced graphene oxide (rGO) via chemical reduction,' in AIP Conference Proceedings, 2015, vol. 1661, no. 1: AIP Publishing LLC, p. 080032. [150] Y.-J. Choi, E. Kim, J. Han, J.-H. Kim, and S. Gurunathan, 'A novel biomolecule-mediated reduction of graphene oxide: a multifunctional anti-cancer agent,' Molecules, vol. 21, no. 3, p. 375, 2016. [151] D. Chao, J. Chen, X. Lu, L. Chen, W. Zhang, and Y. Wei, 'SEM study of the morphology of high molecular weight polyaniline,' Synthetic metals, vol. 150, no. 1, pp. 47-51, 2005. [152] R. C. Silva, M. V. Sarmento, R. Faez, R. J. Mortimer, and A. S. Ribeiro, 'Electrochromic Properties of Polyaniline-Based Hybrid Organic/Inorganic Materials,' Journal of the Brazilian Chemical Society, vol. 27, no. 10, pp. 1847-1857, 2016. [153] H. Saleem, M. Haneef, and H. Y. Abbasi, 'Synthesis route of reduced graphene oxide via thermal reduction of chemically exfoliated graphene oxide,' Materials Chemistry and Physics, vol. 204, pp. 1-7, 2018. [154] B. Ilki et al., 'X-Ray emission spectra of graphene nanosheets,' Journal of nanoscience and nanotechnology, vol. 12, no. 12, pp. 8913-8919, 2012. [155] V. M. Krishna and T. Somanathan, 'Efficient strategy to Cu/Si catalyst into vertically aligned carbon nanotubes with bamboo shape by CVD technique,' Bulletin of Materials Science, vol. 39, no. 4, pp. 1079-1084, 2016. [156] M. Teli, K. K. Samanta, P. Pandit, S. Basak, and S. Chattopadhyay, 'Low-temperature dyeing of silk fabric using atmospheric pressure helium/nitrogen plasma,' Fibers and Polymers, vol. 16, no. 11, pp. 2375-2383, 2015. [157] S. Fang et al., 'Three-dimensional reduced graphene oxide powder for efficient microwave absorption in the S-band (2–4 GHz),' Rsc Advances, vol. 7, no. 41, pp. 25773-25779, 2017. [158] S.-G. Kim, O.-K. Park, J. H. Lee, and B.-C. Ku, 'Layer-by-layer assembled graphene oxide films and barrier properties of thermally reduced graphene oxide membranes,' Carbon Letters (Carbon Lett.), vol. 14, no. 4, pp. 247-250, 2013. [159] C.-M. Chen et al., 'Annealing a graphene oxide film to produce a free standing high conductive graphene film,' Carbon, vol. 50, no. 2, pp. 659-667, 2012. [160] S. H. Aboutalebi et al., 'Comparison of GO, GO/MWCNTs composite and MWCNTs as potential electrode materials for supercapacitors,' Energy Environmental Science, vol. 4, no. 5, pp. 1855-1865, 2011. [161] J. Zhao et al., 'Hydrophilic hierarchical nitrogen‐doped carbon nanocages for ultrahigh supercapacitive performance,' Advanced materials, vol. 27, no. 23, pp. 3541-3545, 2015. [162] K. V. Kumar, K. Preuss, Z. X. Guo, and M. M. Titirici, 'Understanding the hydrophilicity and water adsorption behavior of nanoporous nitrogen-doped carbons,' The Journal of Physical Chemistry C, vol. 120, no. 32, pp. 18167-18179, 2016. [163] M. G. Hosseini and E. Shahryari, 'A novel high-performance supercapacitor based on chitosan/graphene oxide-MWCNT/polyaniline,' Journal of colloid and interface science, vol. 496, pp. 371-381, 2017. [164] Y. Yang et al., 'Electrochemical biosensor based on three-dimensional reduced graphene oxide and polyaniline nanocomposite for selective detection of mercury ions,' Sensors and Actuators B: Chemical, vol. 214, pp. 63-69, 2015. [165] S.-B. Yoon, E.-H. Yoon, and K.-B. Kim, 'Electrochemical properties of leucoemeraldine, emeraldine, and pernigraniline forms of polyaniline/multi-wall carbon nanotube nanocomposites for supercapacitor applications,' Journal of Power Sources, vol. 196, no. 24, pp. 10791-10797, 2011. [166] A. Śliwak, N. Díez, E. Miniach, and G. Gryglewicz, 'Nitrogen-containing chitosan-based carbon as an electrode material for high-performance supercapacitors,' Journal of Applied Electrochemistry, vol. 46, no. 6, pp. 667-677, 2016. [167] R. Klingler and J. Kochi, 'Electron-transfer kinetics from cyclic voltammetry. Quantitative description of electrochemical reversibility,' The Journal of Physical Chemistry, vol. 85, no. 12, pp. 1731-1741, 1981. [168] W. Samaranayake, Y. Miyahara, T. Namihira, S. Katsuki, R. Hackam, and H. Akiyama, 'Ozone production using pulsed dielectric barrier discharge in oxygen,' IEEE Transactions on Dielectrics and Electrical Insulation, vol. 7, no. 6, pp. 849-854, 2000. [169] S. B. Kulkarni et al., 'High-performance supercapacitor electrode based on a polyaniline nanofibers/3D graphene framework as an efficient charge transporter,' Journal of Materials Chemistry A, vol. 2, no. 14, pp. 4989-4998, 2014. [170] V. H. R. de Souza, M. M. Oliveira, and A. J. G. Zarbin, 'Thin and flexible all-solid supercapacitor prepared from novel single wall carbon nanotubes/polyaniline thin films obtained in liquid–liquid interfaces,' Journal of Power Sources, vol. 260, pp. 34-42, 2014. [171] J. Chang et al., 'Activated porous carbon prepared from paulownia flower for high performance supercapacitor electrodes,' Electrochimica Acta, vol. 157, pp. 290-298, 2015. [172] F. Yang, M. Xu, S.-J. Bao, H. Wei, and H. Chai, 'Self-assembled hierarchical graphene/polyaniline hybrid aerogels for electrochemical capacitive energy storage,' Electrochimica Acta, vol. 137, pp. 381-387, 2014.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/78359	-
dc.description.abstract	此研究主要是使用碳纖維布作為軟性超級電容的電極，使用氮氣電弧式常壓噴射電漿在基板溫度520℃將碳纖維布表面處理30秒後，網印塗覆上還原氧化石墨烯-聚苯胺-殼聚醣的奈米複合材料，再使用氬氣介電質放電噴射電漿，在不同處理次數與基板溫度40℃下，對表面材料進行改質，最後均勻塗覆上凝膠態硫酸電解液，製作成一組超級電容。另外，亦有研究以發泡鎳與纖維素紙作為基材之超級電容。經由掃描式電子顯微鏡 (SEM)，可以觀察到還原氧化石墨烯、聚苯胺、殼聚醣的奈米複合材料皆均勻分布在碳纖維布上，而由X-射線繞射儀 (XRD)與拉曼光譜儀 (Raman spectroscopy)觀測到在氬氣介電質放電噴射電漿處理後，材料本身之結構皆沒有明顯的改變。由X-射線光電子能譜儀 (XPS)分析處理前後材料表面的化學組成，利用水接觸角儀 (WCA)測量後，可以發現到在氬氣介電質放電噴射電漿處理後，材料表面之親水性鍵結增加，使得親水性上升，可與凝膠態硫酸電解液有更好的接合，進而提升超級電容之容量。另外，亦有探討電漿處理與熱效應對於碳纖維布之親水性影響。在恆電流充電放電測量法 (Galvanostatic Charge-Discharge Test)與循環伏安法（Cyclic Voltammetry Test）下，可以得到在經過氬氣介電質放電噴射電漿處理後，超級電容具有較大之電雙層電容及法拉第電容，電容值皆提高了150 ~ 300%左右，而在機械式彎曲測試與長時間充放電的實驗下，軟性超級電容經過五百次曲率半徑5 mm的機械彎曲與1萬次充放電後，電容值沒有明顯的降低，顯示出軟性超級電容具有良好的機械穩定性和長時間充放電穩定性。經由此研究的結果顯示，在沒有給予樣品加熱處理下，單純以低溫(~40°C)氬氣介電質放電噴射電漿的高反應性離子，便可以改變碳纖維布上還原氧化石墨烯-聚苯胺-殼聚醣複合材料的性質，使軟性超級電容之性能有進一步的提升。	zh_TW
dc.description.abstract	We used carbon fiber cloth as the electrodes of the flexible supercapacitors. The carbon cloth was treated by nitrogen arc atmospheric-pressure plasma jet (APPJ) at a substrate temperature of 520℃ for 30 s. Following which reduced graphene oxide (rGO)-polyaniline (PANI)-chitosan (CS) pastes was screen-printed on APPJ-treated carbon cloth. Ar dielectric barrier discharge jet (DBDjet) was used to modify the material at a substrate temperature of ~40° C with zero, one, and two scans. Through the scanning electron microscopy, it can be observed that the nanocomposite materials of rGO-PANI-CS are uniformly distributed on the carbon cloth. The structure of the rGO-PANI-CS did not change significantly after the Ar DBDjet treatment. Improved hydrophilicity after DBDjet treatment increased capacity of the supercapacitor, as evidenced by X-ray photoelectron spectroscopy and water contact angle measurement. Galvanostatic charging-discharging (GCD) and cyclic voltammetry (CV) results indicate that Ar DBDjet treatment improves the capacitance by 150 ~ 300%. The flexible supercapacitor shows good stability under the mechanical bending test and long-term charging and discharging experiments. Our results show that without substantial heating, only reactive plasma species of Ar DBDjet can substantially alter the properties of rGO-PANI-CS nanocomposites on carbon cloth to improve the performance of supercapacitors	en
dc.description.provenance	Made available in DSpace on 2021-07-11T14:52:57Z (GMT). No. of bitstreams: 1 U0001-2407202013150800.pdf: 10045190 bytes, checksum: 68929f64d4291dbb73122edaae742b9e (MD5) Previous issue date: 2020	en
dc.description.tableofcontents	口試委員審定書 I 誌謝 II 中文摘要 III ABSTRACT IV 總目錄 V 圖目錄 IX 表目錄 XV 第一章緒論 1 1.1 前言 1 1.2 研究動機 3 1.3 論文大綱 4 第二章基本原理與文獻回顧 5 2.1 超級電容 5 2.1.1 超級電容之介紹 5 2.1.2 超級電容之儲能型式 9 2.1.3 超級電容之組成 15 2.2 常壓電漿 18 2.2.1 電漿之介紹 18 2.2.2 電漿之工作原理 18 2.2.3 常壓電漿之種類與其應用 24 2.3 材料特性 30 2.3.1 石墨烯之介紹 30 2.3.2 聚苯胺之介紹 34 2.3.3 殼聚醣之介紹 38 2.3.4 石墨烯-聚苯胺超級電容之文獻回顧 39 第三章實驗方法與步驟 42 3.1 實驗材料與量測儀器 42 3.2 實驗步驟 45 3.2.1 製備超級電容電極之漿料 45 3.2.2 製備凝膠態電解液 46 3.2.3 製備還原氧化石墨烯-聚苯胺-殼聚醣之電極 46 3.2.4 氮氣直流脈衝常壓噴射電漿 47 3.2.5 網版印刷法 49 3.2.6 氬氣介電質放電電漿 50 3.2.7 製備軟性超級電容 51 3.3 量測儀器介紹 52 3.3.1 掃描式電子顯微鏡 (Scanning Electron Microscope) 52 3.3.2 光放射光譜儀 (Optical Emission Spectroscopy) 55 3.3.3 水接觸角儀 (Water contact angle instrument) 55 3.3.4 X射線繞射儀 (X-ray diffractometer) 57 3.3.5 拉曼光譜儀 (Raman spectroscopy) 58 3.3.6 X射線光電子能譜儀 (X-ray photoelectron spectroscopy) 60 3.3.7 電化學量測 (electrochemical measurement) 61 第四章實驗結果與討論 65 4.1 氮氣直流脈衝常壓噴射電漿處理碳纖維布之溫度分析 65 4.2 氮氣直流脈衝常壓噴射電漿定點處理碳纖維布之光譜分析 66 4.3 碳纖維布之表面型態 67 4.4 碳纖維布之水接觸角量測 69 4.5 氬氣介電質放電電漿掃描處理還原氧化石墨烯-聚苯胺-殼聚醣複合材料之溫度分析 73 4.6 氬氣介電質放電電漿掃描處理還原氧化石墨烯-聚苯胺-殼聚醣複合材料之光譜分析 74 4.7 還原氧化石墨烯-聚苯胺-殼聚醣複合材料之表面型態 75 4.8 還原氧化石墨烯-聚苯胺-殼聚醣複合材料之水接觸角量測 77 4.9 還原氧化石墨烯-聚苯胺-殼聚醣複合材料之晶體結構分析 78 4.10 還原氧化石墨烯-聚苯胺-殼聚醣複合材料之拉曼光譜分析 79 4.11 還原氧化石墨烯-聚苯胺-殼聚醣複合材料之表面化學型態分析 81 4.12 還原氧化石墨烯-聚苯胺-殼聚醣軟性超級電容之循環伏安法量測 86 4.13 還原氧化石墨烯-聚苯胺-殼聚醣軟性超級電容之定電流充放電法量測 89 4.14 還原氧化石墨烯-聚苯胺-殼聚醣軟性超級電容之彎曲穩定性測試 91 4.15 還原氧化石墨烯-聚苯胺-殼聚醣軟性超級電容之多循環次數充放電穩定性測試 94 4.16 還原氧化石墨烯-聚苯胺-殼聚醣軟性超級電容之點亮LED實驗 95 4.17 還原氧化石墨烯-聚苯胺-殼聚醣軟性超級電容之能量密度與功率密度分析 96 第五章結論與未來展望 98 附錄實驗A 電泳還原氧化石墨烯於發泡鎳電極之超級電容應用 100 A.1 摘要 100 A.2 實驗步驟 100 A.3 實驗結果與討論 101 A.3.1發泡鎳超級電容之循環伏安法量測 101 A.3.1發泡鎳超級電容之定電流充放電法量測 103 A.3.1發泡鎳之表面型態 104 A.4 結論 106 附錄實驗B以纖維素紙作為電極之超級電容應用 107 B.1 摘要 107 B.2 實驗步驟 107 B.3 實驗結果與討論 108 B.3.1纖維素紙超級電容之循環伏安法量測 108 B.3.2纖維素紙之表面型態 109 B.4 結論 110 參考文獻 111
dc.language.iso	zh-TW
dc.subject	還原氧化石墨烯	zh_TW
dc.subject	聚苯胺	zh_TW
dc.subject	常壓噴射電漿	zh_TW
dc.subject	超級電容	zh_TW
dc.subject	介電質放電噴射電漿	zh_TW
dc.subject	殼聚醣	zh_TW
dc.subject	Reduced graphene oxide	en
dc.subject	Supercapacitor	en
dc.subject	Polyaniline	en
dc.subject	Dielectric barrier discharge	en
dc.subject	Atmospheric-pressure plasma	en
dc.subject	Chitosan	en
dc.title	常壓介電質放電噴射電漿改質聚苯胺-石墨烯-殼聚醣軟性超級電容及紙基超級電容製程開發	zh_TW
dc.title	Atmospheric-pressure dielectric-barrier-discharge jet modified polyaniline-reduced graphene oxide-chitosan flexible supercapacitors and fabrication process development of paper-based supercapacitors	en
dc.type	Thesis
dc.date.schoolyear	108-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳奕君(I-Chun Cheng),徐振哲(Cheng-Che Hsu),李岳聯(Yueh-Lien Lee)
dc.subject.keyword	超級電容,聚苯胺,還原氧化石墨烯,殼聚醣,介電質放電噴射電漿,常壓噴射電漿,	zh_TW
dc.subject.keyword	Supercapacitor,Polyaniline,Reduced graphene oxide,Chitosan,Dielectric barrier discharge,Atmospheric-pressure plasma,	en
dc.relation.page	120
dc.identifier.doi	10.6342/NTU202001821
dc.rights.note	有償授權
dc.date.accepted	2020-07-24
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	應用力學研究所	zh_TW
dc.date.embargo-lift	2023-07-30	-
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