Mo-doped BaCe0·9Y0·1O3-δ proton-conducting electrolyte at intermediate temperature SOFCs. Part I: Microstructure and electrochemical properties
Author:
Publisher
Elsevier BV
Subject
Energy Engineering and Power Technology,Condensed Matter Physics,Fuel Technology,Renewable Energy, Sustainability and the Environment
Reference75 articles.
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1. Boosting the electrochemical performance of oxygen electrodes via the formation of LSCF-BaCe0.9–xMoxY0.1O3–δ triple conducting composite for solid oxide fuel cells: Part II;Energy;2024-02
2. Theoretical and experimental explored tailored hybrid H+/O2– ions conduction: Bridged for high performance fuel cell and water electrolysis;Chemical Engineering Journal;2024-02
3. Design of a highly stable and conductive electrolyte by suppressing barium copper oxide formation at the grain interfaces in Cux-doped BaCe0.7Zr0.1Dy0.2-xO3-δ sintered at a low temperature (1200 °C) for SOFCs;Journal of Colloid and Interface Science;2024-01
4. Recent advances in microstructural control via thermal spraying for solid oxide fuel cells;Chemical Engineering Journal;2023-12
5. Synergistic role of Biomolecules and Bio-chelating agents in the sustainable development of an efficient BaCe0.97M0.03O3-δ (M = Sm, Gd) perovskite electrolyte for IT-SOFC;Ceramics International;2023-12
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