This research aims to utilize the liquid smoke, charcoal, oil and gas that have been produced from cocoa waste shell from fast pyrolysis technology at 125-500 ^oC. The charcoal of the cocoa waste was analyzed using a bomb calorimeter at 5925 cal/g showed that it contains 52.02% of lignin; 17.27% of alpha cellulose and 19.56% of hemicellulose, respectively. The HPLC analysis of Wajo district cacao bean resulted in polyphenol compound as 308.35. GC-MS analysis of cocoa shell liquid smoke that pyrolized at 125-500 ^oC produces severals compounds such as acetic acid, n-buthane, methyl esther, propanoac acid, butanoac acid, methyl pyridine, 1-hydroxy-2-propanone, and mequinol. The FTIR analysis of cocoa bean showed a hydroxyl group at 3450.65 cm^-1, carbonyl group at 1730.15 cm^-1, CH group at 719.45-607.58 cm^-1. The crystallinity degree of Wajo District cocoa shell analyzed using XRD was 26,50%. The existence of chemical compounds in liquid smoke products have been found as raw chemicals.  Content of biomass carbon at these cacao waste increased according to the increase of pyrolisis temperature, while the carbon emission of these three materials decreased as the temperature increased. Compound polyphenol from cacao bean has a potent as anti oxidant that is friendly  for environmental and healthy.

Keywords: cacao  bean, fermentation,  polyphenol,  and  chemical

Akalin MK, Karagoz S. 2011. Pyrolysis of Tobacco Residue: Part 1. Thermal. J. Biores 6(2): 1520-1531.

Bilmeyer. 1984. Texbook of Polymer Science. New York, John Wiley and Sons.

Bu, Q., Lei, H., Ren, S.J., Wang, L., Holladay, J., Zhang, Q., Tang, J., Ruan, R., 2011. Phenol and phenolics from lignocellulosic biomass by catalytic microwave pyrolysis. Bioresour. Technol. 102, 7004–7007

Bhuiyan MNA, Murakami K, Ota M. 2008. On Thermal Stability and Chemical Kinetic of Water Newspaper by Thermogravimetric and Pyrolysis Analysis. J. Environ. Eng, 3 (1)

Gasparovic L, Korenova Z., Jelemensky L. 2009. Kinetic study of wood chips decomposition by TGA. 36th International Comference of SSCHE

Guo M, and Bi J. 2015. Pyrolysis Characteristics of Corn Stalk with Solid Heat Carrier. J. Bioresources. 10(3), 3839-3851.

Gwenzi, W., Chaukura, N., Mukome, F. N. D., Machado, S., & Nyamasoka, B. (2014). Biochar production and applications in sub-Saharan Africa: Opportunities, constraints, risks and uncertainties. Journal of Environmental Management 150C, 250–261.

Hii, CL, Law, CL, Suzannah, S Misnawi, and Cloke, M 2009. polyphenols in cocoa (theobroma cacaoL.) As. J. Food Ag-Ind. 2009, 2(04), 702-722

Kartal SN, Imamura Y, Tsuchiya F, Ohsato K. 2004. Preliminary Evaluation of Fungicidal and Termiticidal Activity of Filtrates from Biomassa Sharry Fuel Production. J Biores Technol 95 : 41-47

Lv.G.J, Wu.S.B, and Lou. R. 2010. Characteristic of Corn Stalk Hemicelluloce Pyrolysis in a Tubular Reactor. J.Biores. 5(4), 2051-2062

Noor, NM, Shariff A, Abdullah N. 2012. Slow Pyrolysis of Cassava Wastes for Biochar and Characterization. 2012. Iranica J. Energy & Environmental 3. 60-65

Shances O, Boldera P, Rou M, Urena P. 2014. Characterization of Lignocelulosic Fruit Waste as Alternative Feedstock for Bioethanol Production.J. Biores 9(2) : 1873-1885

Wang, D, Li D, Dongcan Lv and Liu Y. 2014. Reduction pf the Variety pf Phenolic Compound in Bio Oil via the Catalytic Pyrolysis. J.Biores 8(3), 4014-4021

Yaman, S., 2004. Pyrolysis of biomass to produce fuels and chemical feedstocks. Energy Convers. Manage. 45, 651–671

Zhu D, Gao. M, Pan H, Pan Y, Liu Y, Li S, Ge H, and Fang N. 2014. Fabrication and mehanical Properties of SiC/SiC-Si Composites by Liquid Si Infiltration using Pyrolysed Rice Husks and SIC Powder as Precursors. 9(2) 2572-2583