Preparation of Porous Carbon by Chlorination of SiC |
Park, Hoey Kyung
(Department of Chemical Engineering, Kongju National University)
Park, Kyun Young (Department of Chemical Engineering, Kongju National University) Kang, Tae Won (Department of Chemical Engineering, Kongju National University) Jang, Hee Dong (Rare Metals Research Center, Korea Institute of Geoscience and Mineral Resources) |
1 | Gogotsi, Y.G., Jeon, J.D., and McNallan, M.J. (1997). Carbon coatings on silicon carbide by reaction with chlorine-containing gases, Journal of Materials Chemistry, 7, 1841-1848. DOI ScienceOn |
2 | Gogotsi, Y., Welz, S., Ersoy, D.A., and McNallan, M.J. (2001). Conversion of silicon carbide to crystalline diamond-structured carbon at ambient pressure, Nature, 411, 283-287. DOI ScienceOn |
3 | Knorr, T., Strobl, F., Glenk, F., and Etzold, B.J.M. (2012). Recommendations for the production of silicon carbide-derived carbon based on intrinsic kinetic data, Chemical Engineering Technology, 35, 1495-1503. DOI ScienceOn |
4 | Knorr, T., Kaiser, M., Glenk, F., and Etzold, B.J.M. (2012). Shrinking core like fluid solid reactions-A dispersion model accounting for fluid phase volume change and solid phase particle size distributions, Chemical Engineering Science, 69, 492-502. DOI ScienceOn |
5 | Kormann, M., Gerhard, H., and Popovska, N. (2009). Comparative study of carbide-derived carbons obtained from bimorphic TiC ansd SiC structures, Carbon, 47, 242-250. DOI ScienceOn |
6 | Lee, A., Zhu, R., and McNallan, M. (2006). Kinetics of caonversion of silicon carbide to carbide derived carbon, Journal of Physics: Condensed Matter, 18, S1763-S1770. DOI ScienceOn |
7 | Mohun, W.A. (1962). Mineral active carbon and process for producing same, US patent 3,066,099. |
8 | Oschatz, M., Kockrick, E., Rose, M., Borchardt, L., Klein, N., Senkovska, I., Freudenberg, T., Korenblit, Y., Yushin, G., and Kaskel, S. (2010). A cubic ordered, mesoporous carbide-derived carbon for gas and energy storage applications, Carbon, 48, 3387-3992. |
9 | Park, K.Y., Park, H.K., Ko, B.W., Kang, T.W., and Jang, H.D. (2012). Recycling of silicon sludge to silicon tetrachloride and porous carbon via chlorination, Industrial and Engineering Chemistry Research, submitted. |
10 | Presser, V., Heon, M., and Gogotsi, Y. (2011). Carbide-derived carbons-From porous networkd to nanotubes and graphene, Advanced Functional Materials, 21, 810-833. DOI ScienceOn |
11 | Rufino, B., Mazerat, S., Couvart, M., Lorrette, C., Maskrot, H., and Pailler, R. (2011). The effect of particle size on the formation and structure of carbon derived carbon on -SiC nanoparticles by reaction with chlorine, Carbon, 49, 3073-3083. DOI ScienceOn |
12 | Schmirler, M., Knorr, T., Fey, T., Lynen, A., Greil, P., and Etzold, B.J.M. (2011). Fast production of monoclinic carbon-derived carbons with secondary porosity produced by chlorination of carbides containing a free metal phase, Carbon, 49, 4359-4367. DOI ScienceOn |
13 | Smorgonskaya, E.A., Kyutt, R.N., Shchukarev, A.V., Gordeev, S.K., and Grechinskaya, A.V. (2001). X-ray studies of nanoporous carbon powders produced from silicon carbide, Semiconductors, 35, 690-694. DOI ScienceOn |
14 | Yushin, G., Dash, R., Jagiello, J., Fischer, J.E., and Gogotsi, Y. (2006). Carbide-derived carbons: Effect of pore size on hydrogen uptake and heat of adsorption, Advanced Functional Materials, 16, 2288-2293. DOI ScienceOn |
15 | Arulepp, M., Leis, J., Latt, M., Miller, F., Rumma, K., Lust, E., and Burke, A.F. (2006). The advanced carbide-derived carbon based supercapacitor, Journal of Power Sources, 162, 1460-1466. DOI ScienceOn |