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Silicon as energy carrier—Facts and perspectives

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  • Auner, Norbert
  • Holl, Sven

Abstract

Due to the diminishing reserves of carbon based primary energy carriers and the need to reduce carbon dioxide (CO2) emissions worldwide, an alternative energy concept was developed using elemental silicon as secondary energy carrier. Starting from sand, silicon can be accessible on a carbon/carbon dioxide free route in a process cycle using cost-effective—at best renewable—energy anywhere in the world. The reduction process sand→silicon, just as the generation of every synthetic secondary energy carrier, requires a significant amount of energy, which then is partially stored in the metal. Using existing technology, silicon can be transported and stored without any risk. Reactions of silicon with oxygen or nitrogen are exothermic and result in the release of thermal energy as well as formation of economically valuable products—instead of CO2. From silicon nitride, ammonia is obtained as a feed stock for the fertilizer industry as well as for hydrogen production. Alternatively, hydrogen is produced from silicon directly by simple reactions with water or alcohols, giving sand or silicon-based compounds as byproducts. These are available for a variety of different technical applications and, if required, can be recycled easily.

Suggested Citation

  • Auner, Norbert & Holl, Sven, 2006. "Silicon as energy carrier—Facts and perspectives," Energy, Elsevier, vol. 31(10), pages 1395-1402.
  • Handle: RePEc:eee:energy:v:31:y:2006:i:10:p:1395-1402
    DOI: 10.1016/j.energy.2005.12.001
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    Citations

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    Cited by:

    1. Bergthorson, Jeffrey M. & Yavor, Yinon & Palecka, Jan & Georges, William & Soo, Michael & Vickery, James & Goroshin, Samuel & Frost, David L. & Higgins, Andrew J., 2017. "Metal-water combustion for clean propulsion and power generation," Applied Energy, Elsevier, vol. 186(P1), pages 13-27.
    2. Maas, Pascal & Schiemann, Martin & Scherer, Viktor & Fischer, Peter & Taroata, Dan & Schmid, Günther, 2018. "Lithium as energy carrier: CFD simulations of LI combustion in a 100MW slag tap furnace," Applied Energy, Elsevier, vol. 227(C), pages 506-515.
    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. Debiagi, P. & Rocha, R.C. & Scholtissek, A. & Janicka, J. & Hasse, C., 2022. "Iron as a sustainable chemical carrier of renewable energy: Analysis of opportunities and challenges for retrofitting coal-fired power plants," Renewable and Sustainable Energy Reviews, Elsevier, vol. 165(C).
    5. Bergthorson, J.M. & Goroshin, S. & Soo, M.J. & Julien, P. & Palecka, J. & Frost, D.L. & Jarvis, D.J., 2015. "Direct combustion of recyclable metal fuels for zero-carbon heat and power," Applied Energy, Elsevier, vol. 160(C), pages 368-382.
    6. Michalsky, Ronald & Parman, Bryon J. & Amanor-Boadu, Vincent & Pfromm, Peter H., 2012. "Solar thermochemical production of ammonia from water, air and sunlight: Thermodynamic and economic analyses," Energy, Elsevier, vol. 42(1), pages 251-260.

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