Nuclear Production of Hydrogen, Fourth Information Exchange ...
Nuclear Production of Hydrogen, Fourth Information Exchange ... Nuclear Production of Hydrogen, Fourth Information Exchange ...
NUCLEAR HYDROGEN USING HIGH TEMPERATURE ELECTROLYSIS AND LIGHT WATER REACTORS FOR PEAK ELECTRICITY PRODUCTION References Anderson, R.E., S.E. Doyle, K.L. Pronske (2004), “Demonstration and Commercialization of Zeroemission Power Plants”, Proc. 29 th International Technical Conference on Coal Utilization & Fuel Systems, Clearwater, FL, USA, 18-22 April. Bossel. U., B. Eliasson (2003), Energy and the Hydrogen Economy, 8 January. Federal Energy Regulatory Commission (FERC) (2004). Form 714 – Annual Electric Control and Planning Area Report, Washington, DC, www.ferc.gov/docs-filing/eforms/form-714/data.asp#skipnavsub. Forsberg, C.W. (2005), Nuclear Hydrogen for Peak Electricity Production and Spinning Reserve, ORNL/ TM-2004/194, Oak Ridge National Laboratory, Oak Ridge, TN. Forsberg, C.W. (2008), “Nuclear Energy for a Low-carbon-dioxide-emission Transportation System with Liquid Fuels”, Nuclear Technology, 164, 348-367, December. Forsberg, C.W. (2009a), “Is Hydrogen the Future of Nuclear Energy?”, Nuclear Technology, 166, 3-10. Forsberg, C.W. (2009b), “Economics of Meeting Peak Electricity Demand Using Hydrogen and Oxygen from Base-load Nuclear or Off-peak Electricity”, Nuclear Technology, 166, 18-26, April. Massachusetts Institute of Technology (MIT) (2007), The Future of Coal: Options for a Carbon-constrained World, Cambridge, MA. Memmott, M.J., et al. (2007), Hydrogen Production by Steam Electrolysis Using a Supercritical CO 2 -cooled Fast Reactor, NIT-NES-TR-007, MIT Center for Advanced Nuclear Energy Systems, February. O’Brien, J.E., et al. (2006), Analysis of Commercial-scale Implementation of HTE to Oil Sands Recovery, DOE Milestone Report, NHI Program, Idaho National Laboratory, Idaho Falls, 15 September. Summers, W.A. (2003), Interim Project Report, Task A.1, Nuclear Hydrogen Plant Definition, NERI Project 02-0160, Centralized Hydrogen Production from Nuclear Power: Infrastructure Analysis and Test-case Design Study, WSRC-TR-2003-00484, Savannah River Technology Center, Aiken, SC, USA. US Department of Energy (US DOE) (2007a), Hydrogen, Fuel Cells & Infrastructure Technology Program: Multi-year Research, Development and Demonstration Program, Office of Energy Efficiency and Renewable Energy, Washington, DC. US DOE (2007b), Technology and Applied R&D Needs for Electrical Energy Storage, Resource Document for the Workshop on Basic Research Needs for Electrical Energy Storage, Office of Science, Washington, DC, 2-3 April. Yildiz, B., K. Hohnholdt, M.S. Kazimi (2004), Hydrogen Production Using High Temperature Steam Electrolysis Supported by Advanced Gas Reactors with Supercritical CO 2 Cycles, Technical Report MIT-NES-TR-002, Center for Advanced Nuclear Energy Systems, Massachusetts Institute of Technology. Yildiz, B., M.S. Kazimi (2006a), “Efficiency of Hydrogen Production Systems Using Alternative Energy Technologies”, International Journal of Hydrogen Energy, 31:77-92. Yildiz, B., K.J. Hohnholt, M.S. Kazimi (2006b), “Hydrogen Production Using High Temperature Steam Electrolysis Supported by Advanced Gas Reactors and Supercritical CO 2 Cycles”, Nuclear Technology, 155(1). 164 NUCLEAR PRODUCTION OF HYDROGEN – © OECD/NEA 2010
SESSION III: THERMOCHEMICAL SULPHUR PROCESS Session III Thermochemical sulphur process Chairs: J. Chang, R. Buckingham NUCLEAR PRODUCTION OF HYDROGEN – © OECD/NEA 2010 165
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NUCLEAR HYDROGEN USING HIGH TEMPERATURE ELECTROLYSIS AND LIGHT WATER REACTORS FOR PEAK ELECTRICITY PRODUCTION<br />
References<br />
Anderson, R.E., S.E. Doyle, K.L. Pronske (2004), “Demonstration and Commercialization <strong>of</strong> Zeroemission<br />
Power Plants”, Proc. 29 th International Technical Conference on Coal Utilization & Fuel Systems,<br />
Clearwater, FL, USA, 18-22 April.<br />
Bossel. U., B. Eliasson (2003), Energy and the <strong>Hydrogen</strong> Economy, 8 January.<br />
Federal Energy Regulatory Commission (FERC) (2004). Form 714 – Annual Electric Control and Planning<br />
Area Report, Washington, DC, www.ferc.gov/docs-filing/eforms/form-714/data.asp#skipnavsub.<br />
Forsberg, C.W. (2005), <strong>Nuclear</strong> <strong>Hydrogen</strong> for Peak Electricity <strong>Production</strong> and Spinning Reserve, ORNL/<br />
TM-2004/194, Oak Ridge National Laboratory, Oak Ridge, TN.<br />
Forsberg, C.W. (2008), “<strong>Nuclear</strong> Energy for a Low-carbon-dioxide-emission Transportation System with<br />
Liquid Fuels”, <strong>Nuclear</strong> Technology, 164, 348-367, December.<br />
Forsberg, C.W. (2009a), “Is <strong>Hydrogen</strong> the Future <strong>of</strong> <strong>Nuclear</strong> Energy?”, <strong>Nuclear</strong> Technology, 166, 3-10.<br />
Forsberg, C.W. (2009b), “Economics <strong>of</strong> Meeting Peak Electricity Demand Using <strong>Hydrogen</strong> and Oxygen<br />
from Base-load <strong>Nuclear</strong> or Off-peak Electricity”, <strong>Nuclear</strong> Technology, 166, 18-26, April.<br />
Massachusetts Institute <strong>of</strong> Technology (MIT) (2007), The Future <strong>of</strong> Coal: Options for a Carbon-constrained<br />
World, Cambridge, MA.<br />
Memmott, M.J., et al. (2007), <strong>Hydrogen</strong> <strong>Production</strong> by Steam Electrolysis Using a Supercritical CO 2 -cooled Fast<br />
Reactor, NIT-NES-TR-007, MIT Center for Advanced <strong>Nuclear</strong> Energy Systems, February.<br />
O’Brien, J.E., et al. (2006), Analysis <strong>of</strong> Commercial-scale Implementation <strong>of</strong> HTE to Oil Sands Recovery, DOE<br />
Milestone Report, NHI Program, Idaho National Laboratory, Idaho Falls, 15 September.<br />
Summers, W.A. (2003), Interim Project Report, Task A.1, <strong>Nuclear</strong> <strong>Hydrogen</strong> Plant Definition, NERI Project<br />
02-0160, Centralized <strong>Hydrogen</strong> <strong>Production</strong> from <strong>Nuclear</strong> Power: Infrastructure Analysis and Test-case Design<br />
Study, WSRC-TR-2003-00484, Savannah River Technology Center, Aiken, SC, USA.<br />
US Department <strong>of</strong> Energy (US DOE) (2007a), <strong>Hydrogen</strong>, Fuel Cells & Infrastructure Technology Program:<br />
Multi-year Research, Development and Demonstration Program, Office <strong>of</strong> Energy Efficiency and Renewable<br />
Energy, Washington, DC.<br />
US DOE (2007b), Technology and Applied R&D Needs for Electrical Energy Storage, Resource Document for the<br />
Workshop on Basic Research Needs for Electrical Energy Storage, Office <strong>of</strong> Science, Washington, DC, 2-3 April.<br />
Yildiz, B., K. Hohnholdt, M.S. Kazimi (2004), <strong>Hydrogen</strong> <strong>Production</strong> Using High Temperature Steam Electrolysis<br />
Supported by Advanced Gas Reactors with Supercritical CO 2 Cycles, Technical Report MIT-NES-TR-002,<br />
Center for Advanced <strong>Nuclear</strong> Energy Systems, Massachusetts Institute <strong>of</strong> Technology.<br />
Yildiz, B., M.S. Kazimi (2006a), “Efficiency <strong>of</strong> <strong>Hydrogen</strong> <strong>Production</strong> Systems Using Alternative Energy<br />
Technologies”, International Journal <strong>of</strong> <strong>Hydrogen</strong> Energy, 31:77-92.<br />
Yildiz, B., K.J. Hohnholt, M.S. Kazimi (2006b), “<strong>Hydrogen</strong> <strong>Production</strong> Using High Temperature Steam<br />
Electrolysis Supported by Advanced Gas Reactors and Supercritical CO 2 Cycles”, <strong>Nuclear</strong> Technology,<br />
155(1).<br />
164 NUCLEAR PRODUCTION OF HYDROGEN – © OECD/NEA 2010