Biblio
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2011.
Technologies and trends in solar power and fuels. Energy & Environmental Science. 4(7):2503.
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2011. .
2012.
Addressing the terawatt challenge: scalability in the supply of chemical elements for renewable energy. RSC Advances. 2(21):7933-7947.
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2012. Atomic layer deposited thin film metal oxides for fuel production in a solar cavity reactor. International Journal of Hydrogen Energy. 37(22):16888-16894.
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2012. Cell failure mechanisms in PEM water electrolyzers. International Journal of Hydrogen Energy. 37(22):17478-17487.
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2012. CO2 valorisation based on Fe3O4/FeO thermochemical redox reactions using concentrated solar energy. International Journal of Energy Research. :n/a-n/a.
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2012. CoFe2O4 on a Porous Al2O3 Nanostructure for Solar Thermochemical CO2 Splitting. Energy & Environmental Science. 5(11):9438-9444.
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2012. Concentrating solar thermal power and thermochemical fuels. Energy & Environmental Science. 5(11):9234-9245.
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2012. Dopant Incorporation in Ceria for Enhanced Water-Splitting Activity During Solar Thermochemical Hydrogen Generation. The Journal of Physical Chemistry C. 116(25):13516–13523.
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2012. The Effects of Morphology on the Oxidation of Ceria by Water and Carbon Dioxide. Journal of Solar Energy Engineering. 134(1):011005.
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2012. Fuel production from CO2 using solar-thermal energy: system level analysis. Energy & Environmental Science. 5(9):8417.
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2012. Low-temperature, manganese oxide-based, thermochemical water splitting cycle. Proceedings of the National Academy of Sciences. 109(24):9260–9264.
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2012. Oxygen Transport and Isotopic Exchange in Iron Oxide/YSZ Thermochemically-active Materials via Splitting of C(18O)2 at High Temperature Studied by Thermogravimetric Analysis and Secondary Ion Mass Spectrometry. Journal of Materials Chemistry. 22(14):6726.
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2012. .
2012. Re-evaluation of the efficiency of a ceria-based thermochemical cycle for solar fuel generation. Chemical Communications.
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2012. .
2012. Syngas production by simultaneous splitting of H2O and CO2 via ceria redox reactions in a high-temperature solar reactor. Energy & Environmental Science. 5(3):6098.
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2012. .
2012. Analysis and improvement of a high-efficiency solar cavity reactor design for a two-step thermochemical cycle for solar hydrogen production from water. Solar Energy. 97:26-38.
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2013. Analytical Model of CeO 2 Oxidation and Reduction. The Journal of Physical Chemistry C. 117(46):24129-24137.
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2013. .
2013. .
2013. Design of Materials for Solar-Driven Fuel Production by Metal-Oxide Thermochemical Cycles. Electrochemical Society Interface. 22(4):63-68.
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2013. High-temperature isothermal chemical cycling for solar-driven fuel production. Physical Chemistry Chemical Physics. 15(40):17084.
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2013.