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Carbothermal reduction of alumina: Thermochemical equilibrium calculations and experimental investigation

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  • Halmann, M.
  • Frei, A.
  • Steinfeld, A.

Abstract

The production of aluminum by the electrolytic Hall–Héroult process suffers from high energy requirements, the release of perfluorocarbons, and vast greenhouse gas emissions. The alternative carbothermic reduction of alumina, while significantly less energy-intensive, is complicated by the formation of aluminum carbide and oxycarbides. In the present work, the formation of Al, as well as Al2OC, Al4O4C, and Al4C3 was proven by experiments on mixtures of Al2O3 and activated carbon in an Ar atmosphere submitted to heat pulses by an induction furnace. Thermochemical equilibrium calculations indicate that the Al2O3-reduction using carbon as reducing agent is favored in the presence of limited amounts of oxygen. The temperature threshold for the onset of aluminum production is lowered, the formation of Al4C3 is decreased, and the yield of aluminum is improved. Significant further enhancement in the carbothermic reduction of Al2O3 is predicted by using CH4 as the reducing agent, again in the presence of limited amounts of oxygen. In this case, an important by-product is syngas, with a H2/CO molar ratio of about 2, suitable for methanol or Fischer–Tropsch syntheses. Under appropriate temperature and stoichiometry of reactants, the process can be designed to be thermo-neutral. Using alumina, methane, and oxygen as reagents, the co-production of aluminum with syngas, to be converted to methanol, predicts fuel savings of about 68% and CO2 emission avoidance of about 91%, vis-à-vis the conventional production of Al by electrolysis and of methanol by steam reforming of CH4. When using carbon (such as coke or petcoke) as reducing agent, fuel savings of 66% and CO2 emission avoidance of 15% are predicted. Preliminary evaluation for the proposed process indicates favorable economics, and the required high temperatures process heat is readily attainable using concentrated solar energy.

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  • Halmann, M. & Frei, A. & Steinfeld, A., 2007. "Carbothermal reduction of alumina: Thermochemical equilibrium calculations and experimental investigation," Energy, Elsevier, vol. 32(12), pages 2420-2427.
    • Handle: RePEc:eee:energy:v:32:y:2007:i:12:p:2420-2427
    DOI: 10.1016/j.energy.2007.06.002
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    References listed on IDEAS

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    1. Halmann, M. & Steinfeld, A., 2006. "Production of lime, hydrogen, and methanol by the thermo-neutral combined calcination of limestone with partial oxidation of natural gas or coal," Energy, Elsevier, vol. 31(10), pages 1533-1541.
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    3. Shkolnikov, E.I. & Zhuk, A.Z. & Vlaskin, M.S., 2011. "Aluminum as energy carrier: Feasibility analysis and current technologies overview," Renewable and Sustainable Energy Reviews, Elsevier, vol. 15(9), pages 4611-4623.
    4. Justus Poschmann & Vanessa Bach & Matthias Finkbeiner, 2023. "Decarbonization Potentials for Automotive Supply Chains: Emission-Intensity Pathways of Carbon-Intensive Hotspots of Battery Electric Vehicles," Sustainability, MDPI, vol. 15(15), pages 1-20, July.
    5. Wang, Guoqiang & Wang, Feng & Li, Longjian & Zhang, Guofu, 2013. "Experiment of catalyst activity distribution effect on methanol steam reforming performance in the packed bed plate-type reactor," Energy, Elsevier, vol. 51(C), pages 267-272.

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