Biblio
Export 122 results:
Author Keyword [ Title] Type Year Filters: First Letter Of Last Name is D [Clear All Filters]
Physical descriptor for the Gibbs energy of inorganic crystalline solids and temperature-dependent materials chemistry. Nature Communications. 9(1):4168.
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2018. A piezomicrobalance system for high-temperature mass relaxation characterization of metal oxides: A case study of Pr-doped ceria. Journal of the American Ceramic Society. 100(3):1161-1171.
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2017. Predicting Oxygen Off-Stoichiometry and Hydrogen Incorporation in Complex Perovskite Oxides. Chemistry of Materials. 34:510-518.
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2022. .
2019. Reduction enthalpy and charge distribution of substituted ferrites and doped ceria for thermochemical water and carbon dioxide splitting with DFT+U. Phys. Chem. Chem. Phys.. 18(34):23587-23595.
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2016. Regulation of Cathode Mass and Charge Transfer by Structural 3D Engineering for Protonic Ceramic Fuel Cell at 400 °C (Adv. Funct. Mater. 33/2021). Advanced Functional Materials. 31:2170244.
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2021. Regulation of Cathode Mass and Charge Transfer by Structural 3D Engineering for Protonic Ceramic Fuel Cell at 400 °C (Adv. Funct. Mater. 33/2021). Advanced Functional Materials. 31:2170244.
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2021. .
2012. Revitalizing interface in protonic ceramic cells by acid etch. Nature. 604:479-485.
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2022. Revitalizing interface in protonic ceramic cells by acid etch. Nature. 604:479-485.
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2022. Revitalizing interface in protonic ceramic cells by acid etch. Nature. 604:479-485.
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2022. Scaleup and manufacturability of symmetric-structured metal-supported solid oxide fuel cells. Journal of Power Sources. 489:229439.
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2021. .
2008. Self-sustainable protonic ceramic electrochemical cells using a triple conducting electrode for hydrogen and power production. Nature Communications. 11
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2020. Self-sustainable protonic ceramic electrochemical cells using a triple conducting electrode for hydrogen and power production. Nature Communications. 11
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2020. Self-sustainable protonic ceramic electrochemical cells using a triple conducting electrode for hydrogen and power production. Nature Communications. 11
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2020. Sensitivity and Effective Parameterization of a Multi-Scale Model of Proton-Exchange-Membrane Water Electrolysis. ECS Transactions. 104(8):417-427.
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2021. Solar photochemical–thermal water splitting at 140 °C with Cu-loaded TiO 2. Energy & Environmental Science. 10(2):628-640.
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2017. Solar thermochemical conversion of CO2 into fuel via two-step redox cycling of non-stoichiometric Mn-containing perovskite oxides. J. Mater. Chem. A. 3(7):3536-3546.
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2015. Solar thermochemical hydrogen production using ceria zirconia solid solutions: Efficiency analysis. International Journal of Hydrogen Energy. 41(42):19320-19328.
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0. Solar thermochemical splitting of water to generate hydrogen. Proceedings of the National Academy of Sciences. :201700104.
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0. Solar thermochemical water-splitting ferrite-cycle heat engines. Journal of Solar Energy Engineering. 130(4):041001(1)-041001(8).
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2008. Solar-to-hydrogen efficiency: shining light on photoelectrochemical device performance. Energy & Environmental Science. 9(1):74-80.
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0. Solar-to-hydrogen efficiency: shining light on photoelectrochemical device performance. Energy & Environmental Science. 9(1):74-80.
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0. Spatially resolved performance and degradation in a perfluorinated anion exchange membrane fuel cell. Electrochimica Acta. 406:139812.
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2022.