Nano-Ceramic Cathodes via Co-sputtering of Gd–Ce Alloy and Lanthanum Strontium Cobaltite for Low-Temperature Thin-Film Solid Oxide Fuel Cells

Abstract

We report the electrochemical performance and structural characteristics of porous nanostructured ceramic cathodes for thin-film solid oxide fuel cells (TF-SOFCs) based on yttria-stabilized zirconia (YSZ) electrolytes. The nanostructured cathode is obtained through magnetron co-sputtering of gadolinium–cerium (Gd–Ce) alloy and lanthanum strontium cobaltite perovskite targets. The resultant nanostructure and composition of the ceramic cathode are controlled by adjusting the co-sputtering conditions. The peak power densities in our fabricated TF-SOFCs are the highest reported values for YSZ-based electrolyte SOFCs, showing 0.14, 0.48, 1.21, 2.56, and 3.01 W/cm2 at 450, 500, 550, 600, and 650 °C, respectively, operating under air and pure hydrogen fuel. The results show that the porosity and composition of the cathode greatly affect the resulting peak power densities. This work illustrates the capability of sputtering to produce stable, scalable, nano-ceramic cathodes with superb peak power densities when integrated in TF-SOFCs.

References

Page 1

	Year	Citations
The analysis of electrode impedances complicated by the presence of a constant phase element G.J. Brug, A.L.G. van den Eeden, M. Sluyters‐Rehbach, Journal of Electroanalytical Chemistry Electrical EngineeringEngineeringElectrode ImpedancesElectrophysiologyConstant Phase Element	1984	3.5K
Influence of the Discretization Methods on the Distribution of Relaxation Times Deconvolution: Implementing Radial Basis Functions with DRTtools Ting Hei Wan, Mattia Saccoccio, Chi Chen, Electrochimica Acta Numerical AnalysisRadial Basis FunctionsDiscretization MethodsNumerical ComputationEngineering	2015	2K
The microstructure of sputter‐deposited coatings John A. Thornton Journal of Vacuum Science & Technology A Vacuum Surfaces and Films EngineeringThin Film Process TechnologySputter‐deposited CoatingsSurface TechnologyEpitaxial Growth	1986	1.3K
Solid oxide fuel cell technology?features and applications Nguyen Q. Minh Solid State Ionics Chemical EngineeringElectrical EngineeringEngineeringOxide ElectronicsAdvanced Energy Technology	2004	865
Electrochemical performance of (La,Sr)(Co,Fe)O3–(Ce,Gd)O3 composite cathodes Erica Perry Murray Solid State Ionics Materials ScienceChemical EngineeringEngineeringAdvanced Electrode MaterialCathode Materials	2002	641
Impedance of Solid Oxide Fuel Cell LSM/YSZ Composite Cathodes Mette Juhl Jørgensen, Mogens Bjerg Mogensen Journal of The Electrochemical Society Materials ScienceChemical EngineeringLsm/ysz ElectrodesEngineeringElectrode-electrolyte Interface	2001	522
Optimal Regularization in Distribution of Relaxation Times applied to Electrochemical Impedance Spectroscopy: Ridge and Lasso Regression Methods - A Theoretical and Experimental Study Mattia Saccoccio, Ting Hei Wan, Chi Chen, Electrochimica Acta Numerical AnalysisElectrical EngineeringEngineeringOptimal RegularizationApproximation Theory	2014	351
Quantitative Comparison of Mixed Conducting SOFC Cathode Materials by Means of Thin Film Model Electrodes F. Baumann, Jürgen Fleig, G. Cristiani, Journal of The Electrochemical Society Materials ScienceElectrical EngineeringChemical EngineeringEngineeringBattery Electrode Materials	2007	223
Three-Dimensional Nanostructured Bilayer Solid Oxide Fuel Cell with 1.3 W/cm<sup>2</sup> at 450 °C Jihwan An, Young‐Beom Kim, Joonsuk Park, Nano Letters Sofc ArchitectureNanosheetEngineeringElectrode-electrolyte InterfaceHigh Power Density	2013	202
High‐Performance Micro‐Solid Oxide Fuel Cells Fabricated on Nanoporous Anodic Aluminum Oxide Templates Chang‐Woo Kwon, Ji‐Won Son, Jong‐Ho Lee, Advanced Functional Materials Materials ScienceElectrical EngineeringChemical EngineeringEngineeringNanoporous Material	2011	168

Page 1