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NTIS 바로가기지하수토양환경 = Journal of soil and groundwater environment, v.27 no.1, 2022년, pp.17 - 24
조동완 (한국지질자원연구원 광물자원연구본부) , 장정윤 (한국지질자원연구원 광물자원연구본부) , 김선준 (한양대학교 자원환경공학과) , 임길재 (한국지질자원연구원 광물자원연구본부)
This work examined the effect of mixing transition metal-based additives [FeCl3, Fe-containing paper mill sludge (PMS), CoCl2·H2O, ZrO2, and α-Fe2O3] on the thermochemical conversion of coffee waste (CW) in carbon dioxide-assisted pyrolysis process. Compared to the generation amounts o...
Atabani, A.E., Al-Muhtaseb, A.H., Kumar, G., Saratale, G.D., Aslam, M., Khan, H.A., Said, Z., and Mahmoud, E., 2019, Valorization of spent coffee grounds into biofuels and value-added products: Pathway towards integrated bio-refinery, Fuel, 254, 115640.
Atabani, A.E., Ali, I., Naqvi, S.R., Badruddin, I.A., Aslam, M., Mahmoud, E., Almomani, F., Juchelkova, D., Atelge, M.R., and Khan, T.M.Y., 2022, A state-of-the-art review on spent coffee ground (SCG) pyrolysis for future biorefinery, Chemosphere, 286, 131730.
Brachi, P., Santes, V., and Torres-Garcia, E., 2021, Pyrolytic degradation of spent coffee ground: A thermokinetic analysis through the dependence of activation energy on conversion and temperature, Fuel, 302, 120995.
Cho, D.W., Cho, S.H., Song, H., and Kwon, E.E., 2015, Carbon dioxide assisted sustainability enhancement of pyrolysis of waste biomass: A case study with spent coffee ground, Bioresource Technol., 189, 1-6.
Cho, D.W., Kwon, E.E., Kwon, G., Zhang, S.C., Lee, S.R., and Song, H., 2017, Co-pyrolysis of paper mill sludge and spend coffee ground using CO 2 as reaction medium, J. CO 2 Util., 21, 572-579.
Cho, D.W., Kim, S., Tsang, D.C.W., Bolan, N.S., Kim, T., Kwon, E.E., Ok, Y.S., and Song, H., 2018, Contribution of pyrolytic gas medium to the fabrication of co-impregnated biochar, J. CO 2 Util., 26, 476-486.
Cho, D.W., Yoon, K., Ahn, Y., Su, Y.Q., Tsang, D.C.W., Hou, D.Y., Ok, Y.S., and Song, H., 2019, Fabrication and environmental applications of multifunctional mixed metal-biochar composites (MMBC) from red mud and lignin wastes, J. Hazard. Mater., 374, 412-419.
Cho, D.-W., Park, J., Kwon, G., Lee, J., Yim, G.J., Jung, W., and Cheong, Y.-W., 2020, Zirconia-assisted pyrolysis of coffee waste in CO 2 environment for the simultaneous production of fuel gas and composite adsorbent, J. Hazard. Mater., 386, 121989.
da Silva, M.R., Bragagnolo, F.S., Carneiro, R.L., Pereira, I.D.C., Ribeiro, J.A.A., Rodrigues, C.M., Jelley, R.E., Fedrizzi, B., and Funari, C.S., 2022, Metabolite characterization of fifteen byproducts of the coffee production chain: From farm to factory, Food Chem., 369, 130753.
Duarte, A., Uribe, J.C., Sarache, W., and Calderon A., 2021, Economic, environmental, and social assessment of bioethanol production using multiple coffee crop residues, Energy, 216, 119170.
Elmously, M., Jager, N., Apfelbacher, A., Daschner, R., and Hornung, A., 2019, Thermo-Catalytic Reforming of spent coffee grounds, Bioresour Bioprocess, 6, 44.
Garcia, C.V. and Kim, Y.T., 2021, Spent coffee grounds and coffee silverskin as potential materials for packaging: A review, J. Polym. Environ., 29, 2372-2384.
Kim, J., Lee, J., Kim, K., Ok, Y., Jeon, Y., and Kwon, E.E., 2017, Pyrolysis of wastes generated through saccharification of oak tree by using CO 2 as reaction medium, Appl. Therm. Eng., 110, 335-345.
Kim, J.H., Jung, S., Kim, J.O., Jeon, Y.J., and Kwon, E.E., 2021, Valorization of carbon dioxide and waste (Derived from the site of Eutrophication) into syngas using a catalytic thermo-chemical platform, Bioresource Technol., 341, 125858.
Kwon, G., Cho, D.W., Wang, H.L., Bhatnagar, A., and Song, H., 2020, Valorization of plastics and paper mill sludge into carbon composite and its catalytic performance for acarbon material consisted of the multi-layerzo dye oxidation, J. Hazard. Mater., 398, 123173.
Liu, M.S., Almatrafi, E., Zhang, Y., Xu, P., Song, B., Zhou, C.Y., Zeng, G.M., and Zhu, Y., 2022, A critical review of biochar-based materials for the remediation of heavy metal contaminated environment: Applications and practical evaluations, Sci. Total. Environ., 806, 150531.
Meng, X.Z., Zhang, Y.Q., Li, Z.X., Wang, H., and Zhang, S.J., 2019, Selective oxidation of amino alcohols to amino acids over au supported on monoclinic ZrO 2 : Dominant active sites and kinetic study, Ind. Eng. Chem. Res., 58(19), 8506-8516.
Qian, K.Z., Kumar, A., Zhang, H.L., Bellmer, D., and Huhnke, R., 2015, Recent advances in utilization of biochar, Renew. Sust. Energ. Rev., 42, 1055-1064.
Rahman, M.A., Lamb, D., Rahman, M.M., Bahar, M.M., Sanderson, P., Abbasi, S., Bari, A.S.M.F., and Naidu, R., 2021, Removal of arsenate from contaminated waters by novel zirco-nium and zirconium-iron modified biochar, J. Hazard. Mater., 409, 124488.
Wan, S.L., Lin, J.D., Tao, W.X., Yang, Y., Li, Y., and He, F., 2019, Enhanced fluoride removal from water by nanoporous biochar-supported magnesium oxide, Ind. Eng. Chem. Res., 58(23), 9988-9996.
Wan, S.L., Qiu, L., Li, Y., Sun, J.J., Gao, B., He, F., and Wan, W.B., 2020, Accelerated antimony and copper removal by manganese oxide embedded in biochar with enlarged pore structure, Chem. Eng. J., 402, 126021.
Williamson, K. and Hatzakis, E., 2019, NMR analysis of roasted coffee lipids and development of a spent ground coffee application for the production of bioplastic precursors, Food Res. Int., 119, 683-692.
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