Biblio
Export 120 results:
Author Keyword Title [ Type] Year Filters: First Letter Of Last Name is G [Clear All Filters]
Evaluating transition metal oxides within DFT-SCAN and $\text{SCAN}+U$ frameworks for solar thermochemical applications. Physical Review Materials. 2(9):095401.
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2018. Exploring Ca–Ce–M–O (M = 3d Transition Metal) Oxide Perovskites for Solar Thermochemical Applications. Chemistry of Materials. 32(23):9964-9982.
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2020. Extreme high temperature redox kinetics in ceria: Exploration of the transition from gas-phase to material-kinetic limitations. Phys. Chem. Chem. Phys.. 18(31):21554-21561.
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2016. Factors Governing Oxygen Vacancy Formation in Oxide Perovskites. Journal of the American Chemical Society. 143(33):13212-13227.
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2021. Failure of PEM water electrolysis cells: Case study involving anode dissolution and membrane thinning. International Journal of Hydrogen Energy. 39(35):20440-20446.
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0. A First-Principles-Based Sub-Lattice Formalism for Predicting Off-Stoichiometry in Materials for Solar Thermochemical Applications: The Example of Ceria. Advanced Theory and Simulations. 3(9)
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2020. Formation of 6H-Ba3Ce0.75Mn2.25O9 During Thermochemical Reduction of 12R-Ba4CeMn3O12: Identification of a Polytype in the Ba(Ce,Mn)O3 Family. Inorganic Chemistry. 61
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2022. Formation of 6H-Ba3Ce0.75Mn2.25O9 During Thermochemical Reduction of 12R-Ba4CeMn3O12: Identification of a Polytype in the Ba(Ce,Mn)O3 Family. Inorganic Chemistry. 61
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2022. Gallium nitride nanowire as a linker of molybdenum sulfides and silicon for photoelectrocatalytic water splitting. Nature Communications. 9(1):3856.
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2018. Gallium nitride nanowire as a linker of molybdenum sulfides and silicon for photoelectrocatalytic water splitting. Nature Communications. 9(1):3856.
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2018. High performance III-V photoelectrodes for solar water splitting via synergistically tailored structure and stoichiometry. Nature Communications. 10:3388.
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2019. High performing triple-conductive Pr2NiO4+δ anode for proton-conducting steam solid oxide electrolysis cell . Journal of Materials Chemistry A. 6:18057-18066.
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2018. Highly efficient and durable III–V semiconductor-catalyst photocathodes via a transparent protection layer. Sustainable Energy Fuels. 4(3):1437-1442.
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2020. Highly efficient and durable III–V semiconductor-catalyst photocathodes via a transparent protection layer. Sustainable Energy Fuels. 4(3):1437-1442.
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2020. High-performance SO2-depolarized electrolysis cell using advanced polymer electrolyte membranes. International Journal of Hydrogen Energy. 47:57-68.
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2022. High-temperature sulfuric acid decomposition over complex metal oxide catalysts. International Journal of Hydrogen Energy. 34(9):4065-4073.
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0. Hydrogen Production From Water Electrolysis: Current Status and Future Trends. Proceedings of the IEEE. 100(2):410-426.
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0. Improved Performance and Efficiency of Lanthanum–Strontium–Manganese Perovskites Undergoing Isothermal Redox Cycling under Controlled pH2O/pH2. Energy & Fuels. 34(12):16918-16926.
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2020. In situ high-temperature powder diffraction studies of solid oxide electrolyte direct carbon fuel cell materials in the presence of brown coal. Journal of Materials Science. 51(8):3928-3940.
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0. An In0.42Ga0.58N tunnel junction nanowire photocathode monolithically integrated on a nonplanar Si wafer. Nano Energy. 57:405-413.
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2019. Incommensurate Sinusoidal Oxygen Modulations in Layered Manganites La 1 − x Sr 1 + x MnO 4 ( x ≥ 0.5 ). Physical Review Letters. 109(10)
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0. Influence of Supporting Electrolyte on Hydroxide Exchange Membrane Water Electrolysis Performance: Anolyte. Journal of The Electrochemical Society. 168:084512.
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2021. Influence of Supporting Electrolyte on Hydroxide Exchange Membrane Water Electrolysis Performance: Anolyte. Journal of The Electrochemical Society. 168:084512.
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2021. Influence of the synthesis route on the formation of 12R/10H-polytypes and their magnetic properties within the Ba(Ce,Mn)O 3 family. New Journal of Chemistry. 39(2):829-835.
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2015. Initial approaches in benchmarking and round robin testing for proton exchange membrane water electrolyzers. International Journal of Hydrogen Energy. 44(18):9174-9187.
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