Biblio
Kinetics and thermodynamics of H2O dissociation on reduced CeO2(111). The Journal of Physical Chemistry C. 118(47):27402-27414.
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0. Kinetics of CO2 reduction over nonstoichiometric ceria. The Journal of Physical Chemistry C. 119(29):16452-16461.
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0. Lanthanum–strontium–manganese perovskites as redox materials for solar thermochemical splitting of H2O and CO2. Energy & Fuels. :130304073847002.
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0. Layer-structured triple-conducting electrocatalyst for water-splitting in protonic ceramic electrolysis cells: Conductivities vs. activity. Journal of Power Sources. 495:229764.
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2021. Long-term stability studies of a semiconductor photoelectrode in three-electrode configuration. Journal of Materials Chemistry A. 7:27612-27619.
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2019. Long-time anodisation of titanium in sulphuric acid. Surface and Coatings Technology. 202(8):1379-1384.
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0. Low-Cost and Durable Bipolar Plates for Proton Exchange Membrane Electrolyzers. Scientific Reports. 7:44035.
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0. Low-Cost, Efficient, and Durable H2 Production by Photoelectrochemical Water Splitting with CuGa3Se5 Photocathodes. ACS Applied Materials & Interfaces. 10(23):19573-19579.
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2018. 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. Low-temperature reducibility of MxCe1–xO2(M = Zr, Hf) under hydrogen atmosphere. The Journal of Physical Chemistry C. 120(1):118-125.
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0. Magnetic and electrical properties of quadruple perovskites with 12 layer structures Ba4LnM3O12 (Ln=rare earths; M=Ru, Ir): The role of metal–metal bonding in perovskite-related oxides. Journal of Solid State Chemistry. 183(9):1962-1969.
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0. Material Analysis of Coated Siliconized Silicon Carbide (SiSiC) Honeycomb Structures for Thermochemical Hydrogen Production. Materials. 6(2):421-436.
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0. Materials for Proton Exchange Membrane water electrolyzer bipolar plates. International Journal of Hydrogen Energy. 42(5):2713-2723.
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0. Materials-Related Aspects of Thermochemical Water and Carbon Dioxide Splitting: A Review. Materials. 5(12):2015-2054.
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0. Maximizing efficiency in two-step solar-thermochemical fuel production. Energy Procedia. 69:1731-1740.
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0. Maximizing fuel production rates in isothermal solar thermochemical fuel production. Applied Energy. 183:1098-1111.
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0. Mechanistic understanding of pH effects on the oxygen evolution reaction. Electrochimica Acta. 405:139810.
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2022. Metal Oxide Composites and Structures for Ultra-High Temperature Solar Thermochemical Cycles. Journal of Materials Science. 43(14):4714-4728.
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0. Metallic nanocatalysts for electrochemical CO2 reduction in aqueous solutions. Journal of Colloid and Interface Science. 527:95-106.
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2018. Metal-Supported Solid Oxide Electrolysis Cell with Significantly Enhanced Catalysis. Energy Technology. 7:1801154.
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2019. Methods for comparing the performance of energy-conversion systems for use in solar fuels and solar electricity generation. Energy & Environmental Science. 8(10):2886-2901.
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2015. Methods of photoelectrode characterization with high spatial and temporal resolution. Energy & Environmental Science. 8(10):2863-2885.
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0. Mg $\less$sub$\greater$x$\less$/sub$\greater$ Zn$\less$sub$\greater$1-x $\less$/sub$\greater$O contact to CuGa$\less$sub$\greater$3$\less$/sub$\greater$Se$\less$sub$\greater$5$\less$/sub$\greater$ absorber for photovoltaic and photoelectrochemical devices. Journal of Physics: Energy. 3:024001.
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2021. Migration of inclusions in a matrix due to a spatially varying interface energy. Scripta Materialia. 206:114235.
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2022. A mini-review on proton conduction of BaZrO 3 -based perovskite electrolytes. Journal of Physics: Energy. 3:032019.
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2021.