Effects of surface etching on microstructure and mechanical strength of carbon fibers |
Kim, Kwan-Woo
(Research Laboratory for Multifunctional Carbon Materials, Korea Institute of Carbon Convergence Technology)
Jeong, Jin-Soo (Department of Organic Materials & Fiber Engineering, Chonbuk National University) Chung, Dong Chul (Research Laboratory for Multifunctional Carbon Materials, Korea Institute of Carbon Convergence Technology) An, Kay-Hyeok (Department of Carbon and Nano Materials Engineering, Jeonju University) Kim, Byung-Joo (Research Laboratory for Multifunctional Carbon Materials, Korea Institute of Carbon Convergence Technology) |
1 | Herrera-Sosa ML. Valadez-Gonzalez A. Vazquez-Torres H. Mani-Gonzalez PG. Herrera-Franco PJ. Effect of the surface modification using MWCNTs with different L/D by two different methods of deposition on the IFSS of single carbon fiber-epoxy resin composite. Carbon Lett, 24, 18 (2017). |
2 | Soutis C. Fiber reinforced composites in aircraft construsction. Prog Aerospace Sci, 41, 143 (2005). DOI |
3 | Paiva MC. Bernardo CA. Nardin M. Mechanical, surface and interfacial characterization of pitch and PAN-based carbon fiber. Carbon, 38, 1323 (2000). DOI |
4 | Dai Z. Zhang B. Shi F. Li M. Zhang Z. Gu Y. Chemical interaction between carbon fibers and surface sizing. App Polym Sci, 124, 2127 (2012). DOI |
5 | Li W. Long D. Miyawaki J. Qiao W. Ling L. Mochida I. Yoon SH. Structural features of polyacrylonitrile-based carbon fibers. Mater sci, 47, 919 (2012). DOI |
6 | Oh SM. Lee SM. Kang DS. Roh JS. Microstructural changes of polyacrylonitrile-based carbon fibers (T300 and T700) due to isothermal oxidation (1): focusing on morphological changes using scanning electron microscopy. Carbon Lett, 18, 18 (2016). DOI |
7 | Kim HI. Choi WK. Oh SY. Seo MK. Park SJ. An KH. Lee YS. Kim BJ. Effects of oxyfluorination on surface and mechanical properties of carbon fiber-reinforced polarized-polypropylene matrix composites. Nanosci Nanotechnol, 14, 9097 (2014). DOI |
8 | Maradur SP. Kim CH. Kim SY. Kim BH. Kim WC, Yang KS. Preparation of carbon fibers from a lignin copolymer with polyacrylonitrile. Synthetic Metals. 162, 453 (2012). DOI |
9 | Qin X. Lu Y. Xiao H. Wen Y. Yu T. A comparison of the effect of graphitization on microstures and properties of polyacrylonitrile and mesophase pitch-based carbon fibers. Carbon, 50, 4459 (2012). DOI |
10 | Edie DD. The effect of processing on the structure and properties of carbon fiber. Carbon, 36, 345 (1998). DOI |
11 | Herrera-Sosa ML. Valadez-Gonzalez A. Vazquez-Torres H. Mani-Gonzalez PG. Herrera-Franco PJ. Effect of the surface modification using MWCNTs with different L/D by two different methods of deposition on the IFSS of single carbon fiber-epoxy resin composite. Carbon Lett, 24, 18 (2017) |
12 | Arbab S. Teimoury A. Mirbaha H. Adolphe DC. Noroozi B. Nourpanah P. Optimum stabilization processing parameters for polyacrylonitrile-based carbon nanofibers and their difference with carbon (micro) fiber, 142, 198 (2017). DOI |
13 | Cipriani E. Zanetti M. Bracco P. Brunella V. Luda M. Costa L. Crosslinking and carbonization processes in PAN films and nanofibers. Polym Degrad Stab, 123, 178 (2016). DOI |
14 | Liu J. Zhou P. Zhang L. Ma Z. Liang J. Fong H. Thermo-chemical reactions occurring during the oxidative stabilization of electrospun polyacrylonitrile precursor nanofibers and the resulting structural conversions. Carbon, 47, 1087 (2009). DOI |
15 | Xie Z. Niu H. Lin T. Continuous polyacrylonitrile nanofiber yarns: preparation and dry-drawing treatment for carbon nanofiber production. RSC Adv, 5, 15147 (2015). DOI |
16 | Wu SH. Qin XH. Effects of the stabilization temperature on the structure and properties of polyacrylonitrile-based stabilized electrospun nanofiber microyarns. Therm Anal Calorim, 116, 303 (2014). DOI |
17 | He JH. Wan YQ. Yu JY. Effect of concentration on electrospun polyacrylonitrile (PAN) nanofibers. Fibers Polym, 9, 140 (2008). DOI |
18 | Lai G. Zhong G. Yue Z. Chen G. Zhang L. Vakili A. Wang Y. Zhu L. Liu J. Fong H. Investigation of post-spinning stretching process on morphological, structural, and mechanical properties of electrospun polyacrylonitrile copolymer nanofibers. Polymer, 52, 519 (2011). DOI |
19 | Arshad SN. Naraghi M. Chasiotis I. Strong carbon nanofibers from electrospun polyacrylonitrile, Carbon, 49, 1710 (2011). DOI |
20 | Sun J. Zhao F. Yao U. Jin Z. Liu X. Huang U. High efficient and continuous surface modification of carbon fibers with improved tensile strength and interfacial adhesion. Applied Surface Science, 412, 424 (2017). DOI |
21 | Baek J. Lee HM. Roh JS. Lee HS. Kang HS. Kim BJ. Studies on preparation and applications of polymeric precursor-based activated hard carbons: I. Activation mechanism and microstructure analyses. Microp Mesop Mat, 219, 258 (2016). DOI |
22 | Vautard F. Dentzer J. Nardin M. Schultz J. Defoort B. Influence of surface defects on the tensile strength of carbon fibers. Appl Surf Sci, 322, 185 (2014). DOI |
23 | Moreton R. Watt W. Tensile strengths of carbon fibres. Nature, 247, 360 (1974). DOI |
24 | Yu W. Yao J. Tensile strength and its variation for PAN-based carbon fibers I. Statistical distribution and volume dependence. Appl. Polym. Sci, 101, 3175 (2006). DOI |
25 | Chae HG. Newcomb BA. Gulgunje PV. Liu Y. Gupa KK. Kamath MG. Lyons KM. Ghoshal S. Pramanik C. Giannuzzi L. Sahin K. Chasiotis I. Kumar S. High strength and high modulus carbon fibers. Carbon, 93, 81 (2015). DOI |
26 | Kim KW. Lee HM. An JH. Chung DC. An KH. Kim BJ. Recycling and characterization of carbon fibers from carbon fiber reinforced epoxy matrix composites by a novel super-heated-steam method. J Environ Manage, 203, 872 (2017). DOI |
27 | Roh JS. Microstructural changes during activation process of isotopic carbon fibers using Gas(I)-XRD Study. Kor J Mater Res, 13, 742 (2003). DOI |
28 | Mathur RB. Bahl OP. Mittal J. Advances in the development of high-performance carbon fibres from PAN precursor. Comp Sci Technol, 51(2), 223 (1993). DOI |
29 | Hao L. Peng P. Yang F. Zhang B. Zhang J. Lu X. Jiao W. Liu W. Wang R. He X. Study of structure-mechanical heterogeneity of polyacrylonitrile-based carbon fiber monofilament by plasma etching-assisted radius profiling. Carbon, 114, 317 (2017). DOI |
30 | Kobayashi T. Sumiya K. Fukuba Y. Fujie M. Takahagi T. Tashiro K. Structural heterogeneity and stress distribution in carbon fiber monofilament as revealed by synchrotron micro-beam X-ray scattering and micro-Raman spectral measurements. Carbon, 49(5), 1646 (2011). DOI |