His primary areas of study are Solid oxide fuel cell, Anode, Oxide, Analytical chemistry and Inorganic chemistry. His studies in Solid oxide fuel cell integrate themes in fields like Yttria-stabilized zirconia, Chemical engineering, Scanning electron microscope and Hydrogen fuel. His Anode research is multidisciplinary, incorporating elements of Open-circuit voltage, Direct energy conversion, Smart material, Electrolyte and Process engineering.
His Oxide research incorporates themes from Electrical engineering and Nickel. His studies in Analytical chemistry integrate themes in fields like Thin film, Sputtering, Epitaxy, Partial pressure and Electrode. The concepts of his Inorganic chemistry study are interwoven with issues in Partial oxidation and Nanoclusters.
His scientific interests lie mostly in Oxide, Solid oxide fuel cell, Analytical chemistry, Chemical engineering and Anode. His Oxide study also includes fields such as
Scott A. Barnett interconnects Doping, Thin film, Sputtering, Scanning electron microscope and Microstructure in the investigation of issues within Analytical chemistry. Scott A. Barnett has researched Chemical engineering in several fields, including Porosity, Electrolysis and Partial oxidation. His Anode research incorporates elements of Yttria-stabilized zirconia and Nickel.
His primary areas of investigation include Oxide, Chemical engineering, Electrode, Solid oxide fuel cell and Cathode. His study on Oxide also encompasses disciplines like
His study in Electrode is interdisciplinary in nature, drawing from both Oxygen transport, Composite material, Nanotechnology and Analytical chemistry. His research integrates issues of Porosity and Perovskite in his study of Solid oxide fuel cell. His Cathode research focuses on subjects like Microstructure, which are linked to Lithium-ion battery.
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A direct-methane fuel cell with a ceria-based anode
E. Perry Murray;T. Tsai;Scott A Barnett.
Advanced anodes for high-temperature fuel cells
Alan Atkinson;Scott A. Barnett;Raymond J. Gorte;John T. Irvine.
Nature Materials (2004)
Three-dimensional reconstruction of a solid-oxide fuel-cell anode
James R. Wilson;Worawarit Kobsiriphat;Roberto Mendoza;Roberto Mendoza;Hsun Yi Chen.
Nature Materials (2006)
Growth of single-crystal TiN/VN strained-layer superlattices with extremely high mechanical hardness
U. Helmersson;S. Todorova;S. A. Barnett;J.‐E. Sundgren.
Journal of Applied Physics (1987)
Electrochemical performance of (La,Sr)(Co,Fe)O3–(Ce,Gd)O3 composite cathodes
E Perry Murray;M.J Sever;S.A Barnett.
Solid State Ionics (2002)
A thermally self-sustained micro solid-oxide fuel-cell stack with high power density
Zongping Shao;Sossina M. Haile;Jeongmin Ahn;Paul D. Ronney.
A perspective on low-temperature solid oxide fuel cells
Zhan Gao;Liliana V. Mogni;Elizabeth C. Miller;Justin G. Railsback.
Energy and Environmental Science (2016)
Model of superlattice yield stress and hardness enhancements
Xi Chu;Scott A. Barnett.
Journal of Applied Physics (1995)
An Octane-Fueled Solid Oxide Fuel Cell
Zhongliang Zhan;Scott A. Barnett.
Growth, structure, and microhardness of epitaxial TiN/NbN superlattices
M. Shinn;L. Hultman;S.A. Barnett.
Journal of Materials Research (1992)
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