Biblio
Thermochemical reactivity of 5–15mol% Fe, Co, Ni, Mn-doped cerium oxides in two-step water-splitting cycle for solar hydrogen production. Thermochimica Acta. 617:179-190.
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0. Thermochemical two-step water splitting by internally circulating fluidized bed of NiFe2O4 particles: Successive reaction of thermal-reduction and water-decomposition steps. International Journal of Hydrogen Energy. 36(8):4757-4767.
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0. Thermochemical Two-Step Water Splitting by ZrO2-supported NixFe3−xO4 for Solar Hydrogen Production. Solar Energy. 82(1):73-79.
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0. Thermodynamic analysis of isothermal redox cycling of ceria for solar fuel production. Energy & Fuels. :130812072357003.
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0. Thermodynamic and kinetic assessments of strontium-doped lanthanum manganite perovskites for two-step thermochemical water splitting. Journal of Materials Chemistry A.
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0. Thermodynamic assessment of an electrically-enhanced thermochemical hydrogen production (EETHP) concept for renewable hydrogen generation. International Journal of Hydrogen Energy. 42(21):14380-14389.
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0. Thermodynamic Considerations for Thermal Water Splitting Processes and High Temperature Electrolysis.
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0. Thermodynamic modeling of the hybrid sulfur (HyS) cycle for hydrogen production. Fluid Phase Equilibria. 460:175-188.
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0. Thermodynamics of CeO2 thermochemical fuel production. Energy & Fuels. :150126104600001.
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0. Three Oxidation States of Manganese in the Barium Hexaferrite BaFe 12– x Mn x O 19. Inorganic Chemistry. 56(7):3861-3866.
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0. Towards Solar Fuels from Water and CO 2. ChemSusChem. 3(2):195-208.
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0. Tunable oxygen vacancy formation energetics in the complex perovskite oxide SrxLa1–xMnyAl1–yO3. Chemistry of Materials. 26(22):6595-6602.
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0. Two-step water splitting thermochemical cycle based on iron oxide redox pair for solar hydrogen production. Energy. 32(7):1124-1133.
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0. Two-step water splitting using mixed-metal ferrites: Thermodynamic analysis and characterization of synthesized materials. Energy & Fuels. 22(6):4115-4124.
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0. T–S diagram efficiency analysis of two-step thermochemical cycles for solar water splitting under various process conditions. Energy. 67:298-308.
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0. Understanding Chemical Expansion in Non-Stoichiometric Oxides: Ceria and Zirconia Case Studies. Advanced Functional Materials. 22(9):1958-1965.
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0. Understanding crystallization pathways leading to manganese oxide polymorph formation. Nature Communications. 9(1):2553.
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0. Understanding the Current-Voltage Behavior of High Temperature Solid Oxide Fuel Cell Stacks. Journal of The Electrochemical Society. 164(13):F1460-F1470.
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0. Understanding the spectroscopic signatures of Mn valence changes in the valence energy loss spectra of Li-Mn-Ni-O spinel oxides. Physical Review Materials. 1(7)
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0. Using computational fluid dynamics modeling to improve the performance of a solar CO2 converter. Industrial & Engineering Chemistry Research. 46(7):1959-1967.
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0. Vacuum pumping options for application in solar thermochemical redox cycles – Assessment of mechanical-, jet- and thermochemical pumping systems. Solar Energy. 141:91-102.
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0. Valence measurement of Mn oxides using Mn K-beta emission spectroscopy. JOURNAL OF PHYSICS AND CHEMISTRY OF SOLIDS. 61(3):547-460.
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0. Validation and characterization of suitable materials for bipolar plates in PEM water electrolysis. International Journal of Hydrogen Energy. 40(35):11385-11391.
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0. Hydrogen production from water utilizing solar heat at high temperatures. Solar Energy. 19(5):467-475.
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1977. Solar thermochemical process technology. Encyclopedia of physical science and technology. 15:237–256.
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2001.