Biblio
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0. System efficiency for two-step metal oxide solar thermochemical hydrogen production – Part 3: Various methods for achieving low oxygen partial pressures in the reduction reaction. International Journal of Hydrogen Energy. 41(44):19881-19893.
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0. System efficiency for two-step metal oxide solar thermochemical hydrogen production – Part 1: Thermodynamic model and impact of oxidation kinetics. International Journal of Hydrogen Energy. 41(44):19881-19893.
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0. Density Functional Theory Modeling of Low-Loss Electron Energy-Loss Spectroscopy in Wurtzite III-Nitride Ternary Alloys. Microscopy and Microanalysis. 22(03):706-716.
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2022. Considerations for the Accurate Measurement of Incident Photon to Current Efficiency in Photoelectrochemical Cells. Frontiers in Energy Research. 9
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0. Evaluation of proton-conducting membranes for use in a sulfur dioxide depolarized electrolyzer. Journal of Power Sources. 195(9):2823-2829.
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0. High-throughput computational screening of perovskites for thermochemical water splitting applications. Chemistry of Materials. 28(16):5621-5634.
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0. Maximizing efficiency in two-step solar-thermochemical fuel production. Energy Procedia. 69:1731-1740.
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2014. Cascading pressure thermal reduction for efficient solar fuel production. International Journal of Hydrogen Energy. 39(25):13114-13117.
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2013. A new reactor concept for efficient solar-thermochemical fuel production. Journal of Solar Energy Engineering. 135(3):031002.
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2016. Design and construction of a cascading pressure reactor prototype for solar-thermochemical hydrogen production. 1734:120001.
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2014. Efficiency maximization in solar-thermochemical fuel production: Challenging the concept of isothermal water splitting. Physical Chemistry Chemical Physics. 16(18):8418.
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2014. Annual Average Efficiency of a Solar-thermochemical Reactor. Energy Procedia. 49:1932-1939.
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0. Methods of photoelectrode characterization with high spatial and temporal resolution. Energy & Environmental Science. 8(10):2863-2885.
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0. Design principles of perovskites for thermochemical oxygen separation. ChemSusChem. 8(11):1966-1971.
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2022. Mechanistic understanding of pH effects on the oxygen evolution reaction. Electrochimica Acta. 405:139810.
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0. Novel rare-earth-containing manganites Ba4REMn3O12 (RE=Ce, Pr) with 12R structure. Journal of Solid State Chemistry. 177(3):714-720.
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0. Solar Thermochemical CO2 Splitting Utilizing a Reticulated Porous Ceria Redox System. Energy & Fuels. 26(11):7051-7059.
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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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2019. Wide-Bandgap Cu(In,Ga)S2 Photocathodes Integrated on Transparent Conductive F:SnO2 Substrates for Chalcopyrite-Based Water Splitting Tandem Devices. ACS Applied Energy Materials. 2(8):5515-5524.
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2021. Performance and Limits of 2.0 eV Bandgap CuInGaS2 Solar Absorber Integrated With CdS Buffer on F:SnO2 Substrate for Multijunction Photovoltaic and Photoelectrochemical Water Splitting Devices. 2(17):5752-5763.
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0. 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. Resonant soft x-ray powder diffraction study to determine the orbital ordering in A-site-ordered SmBaMn 2 O 6. Physical Review B. 77(6)
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2017. Characterizing Voltage Losses in an SO2 Depolarized Electrolyzer Using Sulfonated Polybenzimidazole Membranes. Journal of The Electrochemical Society. 164(14):F1591-F1595.
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2021. Phase formation of manganese oxide thin films using pulsed laser deposition. Mater. Adv.. 2:303-309.
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2018. Evaluating transition metal oxides within DFT-SCAN and $\text{SCAN}+U$ frameworks for solar thermochemical applications. Physical Review Materials. 2(9):095401.