Graphite as one alotrof carbon is widely used as an electrode material for a good electrical conductivity properties. Charcoal as a carbon source material was found very abundant in nature. Charcoal has the potential application for electrode material in energy storage such as in a battery or supercapacitor. For this purpose, charcoal amorphous structure needs to be converted into a graphite structure so that it has better electrical conductivity property. This research aims to prepare the electrical conductor material derived from wood charcoal that could potentially be used as an electrode. Preparation was made by mixing charcoal powder with asphalt binder with a weight ratio of 3:1, 4:1, 5:1 and followed by heat treatment under an inert atmosphere at temperature of 600°C, 800°C and 1000°C. Charcoal material which was originally to be an electrical insulator has been successfully converted into an electrical conductor. The achievement of the optimum temperature to produce electrodes with the smallest electrical resistance is then applied to the manufacture of carbon electrodes by heating a mixture of charcoal and fructose binder in a weight ratio of 1:1 (w/w). The results showed electrodes with a mixture of charcoal powder and fructose with heat treatment at 1000°C has the better electrical conductivity among other variations.

Austin, A. E. and Hedden, W. A., 1954. Graphitization Processes in Cokes and Carbon Blacks. Industrial & Engineering Chemistry 46 (7), 1520-1524.

Bourke, J., Manley-Harris, M., Fushimi, C., Dowaki, K., Nunoura, T., and Antal, M. J., 2007. Do All Carbonized Charcoals Have the Same Chemical Structure 2. A Model of the Chemical Structure of Carbonized Charcoal. Industrial & Engineering Chemistry Research 46 (18), 5954-5967.

Coutinho, A. R., Rocham J. D., and Luengo, C. A., 2000. Preparing and characterizing biocarbon electrodes. Fuel Processing Technology 67 (2), 93-102.

Das, B., Dadhich, P., Pal, P., Srivas, P. K., Bankoti, K., and Dhara, S., 2014. Carbon nanodots from date molasses: new nanolights for the in vitro scavenging of reactive oxygen species. Journal of Materials Chemistry B 2 (39), 6839-6847.

Gang-Wei, S., Can, W., Liang, Z., Wen-Ming, Q., Xiao-Yi, L., and Li-Cheng, L., 2008. Influence of high temperature treatment of activated carbon on performance of supercapacitors. Journal of Materials Science & Engineering 2 (12), 8.

Hishiyama, Y., Inagaki, M., Kimura, S. and Yamada, S., 1974. Graphitization of carbon fibre/ glassy carbon composites. Carbon 12 (3), 249-258.

Jain, A. and Tripathi, S. K., 2014. Fabrication and characterization of energy storing supercapacitor devices using coconut shell based activated charcoal electrode. Materials Science and Engineering: B 183, 54-60.

Marsh, H. and Warburton, A. P., 1970. Catalysis of graphitisation. Journal of Applied Chemistry 20 (4), 133-142.

Okada, J., Sekiguchi, A., and Ishii, T., 1961. Effect of Rapid Heat Treatment on The Properties of Carbon. The Fifth Conference on Carbon, Pennsylvania State University, University Park, Pennsylvania, Pergamon Press.

Pierson, H. O., 1994. Handbook of Carbon, Graphite, Diamonds and Fullerenes (Processing, Properties and Applications). Park Ridge, New Jersey, USA, Elsevier Inc.

Tanahashi, I., Yoshida, A., and Nishino, A., 1991. The effect of heat-treatment on the properties of activated carbon fibre cloth polarizable electrodes. Journal of Applied Electrochemistry 21 (1), 28-31.

Wen, G., Sui, S. H., Song, L., Wang, X. Y., and Xia, L., 2010. Formation of ZrC ablation protective coatings on carbon material by tungsten inert gas cladding technique. Corrosion Science 52 (9), 3018-3022.

Yan, H., Zhao, T., Li, X., and Hun, C., 2015. Detonation Synthesis and Friction-Wear Test of Carbon-Encapsulated Copper Nanoparticles. Journal of Inorganic and Organometallic Polymers and Materials 25 (6), 1569-1575.