1. Oxygen ion conductivity in ceria-based electrolytes co-doped with samarium and gadolinium
- Author
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Alice V. Coles-Aldridge, Richard T. Baker, University of St Andrews. School of Chemistry, University of St Andrews. St Andrews Sustainability Institute, and University of St Andrews. EaSTCHEM
- Subjects
Materials science ,Chemistry(all) ,Analytical chemistry ,Oxide ,chemistry.chemical_element ,02 engineering and technology ,Conductivity ,010402 general chemistry ,01 natural sciences ,Concentration ratio ,chemistry.chemical_compound ,Ceria ,Ionic conductivity ,Materials Science(all) ,Solid oxide fuel cell ,Electrolyte ,Activation energy ,Doping ,General Materials Science ,QD ,Dopant ,DAS ,General Chemistry ,021001 nanoscience & nanotechnology ,QD Chemistry ,Condensed Matter Physics ,0104 chemical sciences ,Samarium ,chemistry ,Grain boundary ,0210 nano-technology - Abstract
The authors thank the University of St Andrews and the UK Engineering and Physical Sciences Research Council for the PhD studentship for AVC-A (grant code: EP/M506631/1). Electron microscopy was performed at the Electron Microscope Facility, University of St Andrews. In a systematic study, two compositional series of ceria-based oxides, both co-doped with Sm and Gd, were synthesised using a low temperature method and evaluated as oxygen ion-conducting electrolytes for Intermediate Temperature Solid Oxide Fuel Cells (IT-SOFCs). Series one, Ce1-2xSmxGdxO2-x, had equal concentrations of Sm and Gd but varying total dopant concentration. Series two, Ce0.825SmxGd0.175-xO1.9125, had a fixed total dopant concentration but the Sm:Gd concentration ratio was varied. The materials were characterised using scanning and transmission electron microscopy, inductively coupled plasma mass spectrometry and X-ray diffraction. Impedance spectra were recorded on dense pellets of these materials. From these, total, bulk and grain boundary conductivities and capacitances along with activation energies, pre-exponential constants and enthalpies of ion migration and defect association were obtained. These gave a detailed insight into the fundamental conduction processes in the materials. Ce0.825Sm0.0875Gd0.0875O1.9125 had the highest total ionic conductivity at temperatures of 550 °C and above and also demonstrated an enhanced conductivity with respect to its singly-doped parent compounds, Ce0.825Sm0.175O1.9125 and Ce0.825Gd0.175O1.9125, at 400 °C and above. This compares favourably with previously-reported values and has promising implications for the development of IT-SOFCs. Postprint
- Published
- 2020