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Graphene Synthesis, Catalysis with Transition Metals and Their Interactions by Laser Photolysis 77 [14] Bhaviripudi, S., Jia, X., Dresselhaus, M.S., Kong, J., Role of kinetic factors in chemical vapor deposition synthesis of uniform large area graphene using copper catalyst, Nano Letters 10 (10), pp. 4128-4133 (2010) [15] Kholmanov, I.N., Cavaliere, E., Cepek, C., Gavioli, L., Catalytic chemical vapor deposition of methane on graphite to produce graphene structures, Carbon 48 (5), pp. 1619-1625 (2010) [16] Wang, X., You, H., Liu, F., Li, M., Wan, L., Li, S., Li, Q., (...), Cheng, J., Large-scale synthesis of few-layered graphene using CVD, Chemical Vapor Deposition 15 (1-3), 53-56 (2009) [17] Malesevic, A., Vitchev, R., Schouteden, K., Volodin, A., Zhang, L., Tendeloo, G.V., Vanhulsel, A., Haesendonck, C.V., Synthesis of few-layer graphene via microwave plasma-enhanced chemical vapour deposition, Nanotechnology 19 (30), art. no. 305604 (2008) [18] Cambaz, Z.G., Yushin, G., Osswald, S., Mochalin, V., Gogotsi, Y., Noncatalytic synthesis of carbon nanotubes, graphene and graphite on SiC, Carbon 46 (6), pp. 841-849 (2008) [19] Nakajima, T., Koh, M., Takashima, M., Electrochemical behavior of carbon alloy CxN prepared by CVD using a nickel catalyst, Electrochimica Acta 43 (8), 883-891 (1997) [20] Nakajima, T., Koh, M., Synthesis of high crystalline carbon-nitrogen layered compounds by CVD using nickel and cobalt catalysts, Carbon 35 (2), pp. 203-208 (1997) [21] Rümmeli, M.H., Kramberger, C., Grüneis, A., Ayala, P., Gemming, T., Büchner, B., Pichler, T., On the graphitization nature of oxides for the formation of carbon nanostructures, Chemistry of Materials 19 (17), 4105-4107 (2007) [22] Volotskova, O., Levchenko, I., Shashurin, A., Raitses, Y., Ostrikov, K., Keidar, M., Single-step synthesis and magnetic separation of graphene and carbon nanotubes in arc discharge plasmas, Nanoscale 2 (10), 2281-2285 (2010) [23] Li, B.-J., Kung, S.-C., Hsu, C.-M., Gao, J.-Y., Lai, H.-J., Preparation of a new carbon nano- partlcle by arc discharge, Materials Research Society Symposium Proceedings 822, art. no. S6.12, pp. 115-120 (2004) [24] Fei Tan, K., Xu, J., Chang, J., Borgna, A., Saeys, M., Carbon deposition on Co catalysts during Fischer-Tropsch synthesis: A computational and experimental study, Journal of Catalysis 274 (2), 121-129 (2010) [25] Swart, J.C.W., Van Steen, E., Ciobíč, I.M., Van Santen, R.A., Interaction of graphene with FCC-Co(111), Physical Chemistry Chemical Physics 11 (5), pp. 803-807 (2009) [26] Nolan, P.E., Lynch, D.C., Cutler, A.H., Carbon deposition and hydrocarbon formation on group VIII metal catalysts, Journal of Physical Chemistry B 102 (21), 4165-4175 (1998) [27] Parvizi, F., Teweldebrhan, D., Ghosh, S., Calizo, I., Balandin, A.A., Zhu, H., Abbaschian, R. Cabioc'h, T., Naudon, A., Jaouen, M., Thiaudiére, D., Babonneau, D., Co- sputtering C - Cu thin film synthesis: Microstructural study of copper precipitates encapsulated into a carbon matrix, Philosophical Magazine B: Physics of Condensed Matter; Statistical Mechanics, Electronic, Optical and Magnetic Properties 79 (3), pp. 501-516 (1999) [28] Jee, A.-Y., Lee, M., Synthesis of two dimensional carbon sheets from adamantane, Carbon 47 (10), 2546-2548 (2009)PDF Image | GRAPHENE SYNTHESIS CHARACTERIZATION PROPERTIES
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