TEP
Clark School UMD Home Clark School Home

Solid Oxide Fuel Cells

Publications

Electrolyte

“Dysprosium and Gadolinium Double Doped Bismuth Oxide Electrolytes for Low Temperature Solid Oxide Fuel Cells,” D.W. Jung, K.T. Lee, and E.D. Wachsman, Journal of The Electrochemical Society, 163, F411-4145 (2016).

“Terbium and Tungsten Co-doped Bismuth Oxide Electrolytes for Low Temperature Solid Oxide Fuel Cells” D.W. Jung, K.T. Lee, and E.D Wachsman, Journal of the Korean Ceramic Society, 51, 260-264 (2014).

"Highly Functional Nano-scale Stabilized Bismuth Oxides via Reverse Strike Co-precipitation for Solid Oxide Fuel Cells" K.T. Lee, A.A. Lidie, S.Y. Jeon, G.T. Hitz, and E. D. Wachsman, Journal of Materials Chemistry, 1, 6199-6207 (2013) DOI: 10.1039/c3ta10570a

“Performance of La0.1Sr0.9Co0.8Fe0.2O3-d and La0.1Sr0.9Co0.8Fe0.2O3-d-Ce0.9Gd0.1O2 Oxygen Electrodes with Ce0.9Gd0.1O2 Barrier Layer in Reversible Solid Oxide Fuel Cells,” M.-B. Choi, B. Singh, E. D. Wachsman, and S.-J. Song, Journal of Power Sources, 239, 361-373 (2013).

"The Evolution of Low Temperature Solid Oxide Fuel Cells,” K. T. Lee, H. S. Yoon, and E. D. Wachsman, Journal of Materials Research, 27, 2063-2078 (2012) - Invited Feature Paper.

"Role of Solid Oxide Fuel Cells in a Balanced Energy Strategy,” E. D. Wachsman, C. A. Marlowe and K. T. Lee, Energy and Environmental Science, 5, 5498-5509 (2012) DOI:10.1039/c1ee02445k - Invited Analysis.

"Gd0.1Ce0.9O1.95/Er0.4Bi1.6O3 Bilayer Electrolytes Fabricated by a Simple Colloidal Route using Nano-Sized in Er0.4Bi1.6O3 Powders for High Performance LT-SOFCs," K. T. Lee, D. W. Jung, M. A. Camaratta, H. S. Yoon, J. S. Ahn, and E. D. Wachsman, Journal of Power Sources, 205, 122-128 (2012).

"Lowering the Temperature of Solid Oxide Fuel Cells,” E. D. Wachsman and K. T. Lee, Science, 334, 935-939 (2011) - Invited Review.

“High Performance LSM-ESB Cathode on ESB Electrolyte for Low to Intermediate Temperature Solid Oxide Fuel Cells,” K.T. Lee, D.W. Jung, H.S. Yoon, M.A. Camarratta, N.A. Sexson, and E.D. Wachsman, Solid Oxide Fuel Cells XII, ECS Transactions, S.C. Singhal, and K. Eguchi, Ed, 35, 1955-1963 (2011).

“Proton Conduction in Acceptor Doped SnP2O7,” S. R. Phadke, C. R. Bowers, E. D. Wachsman, and J. C. Nino, Solid State Ionics, 183, 26-31 (2011).

"Dependence of Open-Circuit Potential and Power Density on Electrolyte Thickness in Solid Oxide Fuel Cells with Mixed Conducting Electrolytes," K. L. Duncan, K. T. Lee, and E. D. Wachsman, Journal of Power Sources, 196, 2445-2451 (2011).

“Effect of La2Zr2O7 on Interfacial Resistance in Solid Oxide Fuel Cells,” A. Chen, J. Smith, K. Duncan, R.T. DeHoff, K. Jones, and E. D. Wachsman, Journal of the Electrochemical Society, 157, B1624-B1628 (2010).

“A Critical Assessment of Interatomic Potentials for Ceria with Application to its Elastic Properties,” H. Xu, R. K. Behera, Y. Wang, F. Ebrahimi, S. B. Sinnott, E. D. Wachsman, and S. R. Phillpot, Solid State Ionics, 181, 551-556 (2010).

"Enhanced Long-Term Stability of Bismuth Oxide-Based Electrolytes for Operation at 500°C," D. W. Jung, J. C. Nino, K. L. Duncan, S. R. Bishop, and E. D. Wachsman, Ionics, 16, 97-103 (2010).

“Development of High Performance Ceria/Bismuth Oxide Bilayered Electrolyte SOFCs for Lower Temperature Operation,” J. S. Ahn, M. A. Camaratta, D. Pergolesi, K. T. Lee, H. Yoon, B. W. Lee, D. W. Jung, E. Traversa and E. D. Wachsman, Journal of The Electrochemistry Society, 157, B376-382 (2010).

“Performance of IT-SOFC with Ce0.9Gd0.1O0.1.95 Functional Layer at the Interface of Ce0.9Gd0.1O0.1.95 Electrolyte and Ni- Ce0.9Gd0.1O0.1.95 Anode,” J. S. Ahn, H. Yoon, K. T. Lee, M. Camaratta, and E. D. Wachsman, Fuel Cells, 9, 643-649 (2009).

“Surface and Bulk Defect Equilibria in Strontium Doped Lanthanum Cobalt Iron Oxide,” S.R. Bishop, K. L. Duncan, and E. D. Wachsman, Journal of the Electrochemical Society, 156, B1242-1248 (2009).

“Development of a Lower Temperature SOFC,” E.D. Wachsman, Solid Oxide Fuel Cells XI, ECS Transactions, S.C. Singhal, and H. Yokokawa, Ed, 25-2, 783-788 (2009).

“Continuum - Level Analytical Model for Solid Oxide Fuel Cells with Mixed Conducting Electrolytes,” K. L. Duncan and E. D. Wachsman, Journal of the Electrochemical Society, 156, B1030-1038 (2009).

“High-Performance Bilayered Electrolyte Intermediate Temperature Solid Oxide Fuel Cells,” J. S. Ahn, D. Pergolesi, M. A. Camaratta, H. Yoon, B. W. Lee, E. Traversa and E. D. Wachsman, Electrochemistry Communications, 11, 1504-1507 (2009).

“High Performance Ceria/Bismuth Oxide Bilayered Electrolyte IT-SOFC,” J. S. Ahn, M. Camaratta, K.T. Lee, H. S. Yoon, B. W. Lee, and E.D. Wachsman, ECS Transactions, 16-51, 135 (2009).

“Higher Conductivity Sm3+ and Nd3+ Co-Doped Ceria-Based Electrolyte Materials,” S. Omar, E. D. Wachsman, and J. C. Nino, Solid State Ionics, 178, 1890-1897 (2008).

“Higher Ionic Conductive Ceria Based Electrolytes for SOFCs,” S. Omar, E. D. Wachsman, and J. C. Nino, Applied Physics Letters, 91, 1444106 (2007).

“A Co-doping Approach Towards Enhanced Ionic Conductivity in Fluorite Based Electrolytes,” S. Omar, E. D. Wachsman, and J. C. Nino, Solid State Ionics, 177, 3199-3203 (2006).

“Applicability of Bi2Ru2O7 Pyrochlore Electrodes for ESB and BiMEVOX Electrolytes,” V. Esposito, B.H. Luong, E.D. Bartolomeo, E.D. Wachsman, and E. Traversa, Journal of the Electrochemical Society, 153, A2232-A2238 (2006).

“Stable and High Conductivity Bilayered Electrolytes for Lower Temperature Solid Oxide Fuel Cells,” J.Y. Park and E.D. Wachsman, Ionics, 12-1, 15-20 (2006).

“Thermo-Chemical Expansion of SOFC Materials,” S.R. Bishop, K.L. Duncan, and E. D. Wachsman, Solid State Ionic Devices IV, ECS Transactions, E.D. Wachsman, F.H. Garzon, E. Traversa, R. Mukundan, and V. Birss, Ed., 1-7, 13-22 (2006).

“Development of Higher Ionic Conductivity Ceria Based Electrolyte,” S. Omar, E. D. Wachsman, and J. C. Nino, Solid State Ionic Devices IV, ECS Transactions, E.D. Wachsman, F.H. Garzon, E. Traversa, R. Mukundan, and V. Birss, Ed., 1-7, 73-82 (2006).

“Doubly Doped Bi2O3 Electrolytes with Higher Conductivity,” D.W. Jung, K.L. Duncan, and E. D. Wachsman, Solid State Ionic Devices IV, ECS Transactions, E.D. Wachsman, F.H. Garzon, E. Traversa, R. Mukundan, and V. Birss, Ed., 1-7, 63-72 (2006).

“Screen-Printed Dense Yttria-Stabilized-Zirconia Electrolytes for Anode-Supported Solid Oxide Fuel Cells,” B. M. White, M. L. Grilli, E. Traversa, E. Roncari, F. Pittalis, E. D. Wachsman and A. Sanson, Solid State Ionic Devices IV, ECS Transactions, E.D. Wachsman, F.H. Garzon, E. Traversa, R. Mukundan, and V. Birss, Ed., 1-7, 83-94 (2006).

“Bi2Ru2O7 Pyrochlore Electrodes for Bi2O3 Based Electrolyte for IT-SOFC Applications,” V. Esposito, B. H. Luong, E. Di Bartolomeo, E. D. Wachsman, and E. Traversa, Solid State Ionic Devices IV, ECS Transactions, E.D. Wachsman, F.H. Garzon, E. Traversa, R. Mukundan, and V. Birss, Ed., 1-7, 263-278 (2006).

“Direct Current Bias Studies on (Bi2O3)0.8(Er2O3)0.2 Electrolyte and Ag-(Bi2O3)0.8(Er2O3)0.2 Cermet Electrode,” A. Jaiswall and E.D. Wachsman, Solid State Ionics, 177 (7-8), 677-685 (2006).

“Pb2Ru2O6.5 as a Low-Temperature Cathode for Bismuth Oxide Electrolytes,” V. Esposito, E. Traversa, and E.D. Wachsman, Journal of the Electrochemical Society, 152 (12), A2300-2306 (2005).

“Fabrication and Characterization of High-Conductivity Bilayered Electrolytes for Intermediate-Temperature Solid Oxide Fuel Cells,” J.Y. Park and E.D. Wachsman, Journal of the American Ceramic Society, 88 [9], 2402-2408 (2005).

“Fabrication of Anode Supported Thick Film Ceria Electrolytes for IT-SOFCs,” A. Jaiswal and E.D. Wachsman, Ionics, 11, 161-170 (2005).

“Lower Temperature Electrolytic Reduction of CO2 to O2 and CO with High Conductivity Solid Oxide Bilayer Electrolytes,” J.Y. Park and E.D. Wachsman, Journal of the Electrochemical Society, 152 (8), A1654-1659 (2005).

“RuO2–Based Dense Electrodes for ESB Electrolyte IT-SOFCs,” V. Esposito, E. Traversa, and E.D. Wachsman, Solid Oxide Fuel Cells IX, Electrochem. Soc., S.C. Singhal and J. Mizusaki, Ed, 2005-07, 1764-1772 (2005).

“Modeling the Performance and Stability of Bilayer Electrolytes for Low-Temperature Solid Oxide Fuel Cells,” K.L. Duncan and E.D. Wachsman, Solid State Ionic Devices III, Electrochem. Soc., E.D. Wachsman, K.S. Lyons, M. Carolyn, F. Garzon, M. Liu, and J. Stetter, Ed., 2002-26, 308-318 (2003).

“Stable High Conductivity Bilayered Electrolytes for Low Temperature Solid Oxide Fuel Cells,” J.Y. Park and E.D. Wachsman, Solid Oxide Fuel Cells VIII, Electrochem. Soc., S.C. Singhal and M. Dokiya, Ed, 2003-07, 289-298 (2003).

"A Higher Conductivity Bi2O3-Based Electrolyte," N. Jiang, E. D. Wachsman, and S. H. Jung, Solid State Ionics, 150, 347-353 (2002).

"Structural Stability and Conductivity of (WO3)x(Dy2O3)y(Bi2O3)1-x-y," S. H. Jung, E. D. Wachsman, and N. Jiang, Ionics, 8, 210-214 (2002).

"Ceria/Bismuth Oxide Bilayered Electrolytes for Low Temperature Solid Oxide Fuel Cells," E. D. Wachsman and K. L. Duncan, SOFC-VI, Electrochem. Soc., S.C. Singhal, Ed., 99-19, 264-274 (1999).

"Stable High Conductivity Ceria/Bismuth Oxide Bilayered Electrolytes," E. D. Wachsman, P. Jayaweera, N. Jiang, D. M. Lowe, and B.G. Pound, Journal of the Electrochemical Society, 144-1, 233-236 (1997).

"Structural and Defect Studies in Solid Oxide Electrolytes," E. D. Wachsman, G. R. Ball, N. Jiang, and D. A. Stevenson, Solid State Ionics, 52, 213-218 (1992).

"Spectroscopic Investigation of Oxygen Vacancies in Solid Oxide Electrolytes," E. D. Wachsman, N. Jiang, C. W. Frank, D. M. Mason, and D. A. Stevenson, Applied Physics A 50, 545-549 (1990).

"Electrochemical Abatement of Pollutants NOx and SOx in Coal Combustion Exhaust Gases Employing a Solid Oxide Electrolyte," E. D. Wachsman, N. Jiang, D. M. Mason, and D. A. Stevenson, Proceedings of the 1989 International Conference on Coal Science, Tokyo, Japan 1103-1106 (1989).

Return to Top

Return to Solid Oxide Fuel Cells

 
 


Home