Journal article
Enhanced surface exchange activity and electrode performance of (La2–2xSr2x)(Ni1–xMnx)O4+δ cathode for intermediate temperature solid oxide fuel cells
Journal of power sources, Vol.318(C), pp.178-183
06/30/2016
Web of Science ID: WOS:000376051300021
Abstract
Surface exchange kinetics of Ruddlesden-Popper (R-P) phase lanthanum nickelates upon Mn doping as an intermediate temperature solid oxide fuel cells (IT-SOFCs) cathode is investigated for the first time in this communication. To promote the exchange rate in oxygen reduction reaction (ORR) on nickelates, Mn is partially substituted for Ni. The oxygen exchange resistance is accurately measured by electrochemical impedance spectroscopy (EIS) with dense thin layer cathode. It is found that Mn substantially promotes the surface kinetics; a surface exchange coefficient (k) of 1.57 x 10(-6) cm/s is obtained at 700 degrees C for La1.8Sr0.2Ni0.9Mn0.1O4+delta (Sr20Mn10), similar to 80% higher than that of the undoped La2NiO4+delta (LNO). To our best knowledge, such coefficient is the highest values among the currently available R-P phase IT-SOFC cathodes. The corresponding polarization resistances (R-p) are evaluated on porous electrodes. R-p for LNO is 0.74 Omega cm(2) at 750 degrees C, but decreases significantly to 0.42 Omega cm(2) for Sr20Mn10 which is remarkably improved compared to the reported values in the literature for La2MO4+delta materials (M = transition metal). Those promising results demonstrate that Mn-doped LNO is a new excellent cathode material for IT-SOFC.
Details
- Title
- Enhanced surface exchange activity and electrode performance of (La2–2xSr2x)(Ni1–xMnx)O4+δ cathode for intermediate temperature solid oxide fuel cells
- Publication Details
- Journal of power sources, Vol.318(C), pp.178-183
- Resource Type
- Journal article
- Publisher
- Elsevier
- Number of pages
- 6
- Grant note
- DE-FE00009675 / US Department of Energy's Solid Oxide Fuel Cell program
- Copyright
- © 2016 Elsevier B.V. All rights reserved.
- Identifiers
- WOS:000376051300021; 99381656067206600
- Academic Unit
- Mechanical Engineering; Hal Marcus College of Science and Engineering
- Language
- English