Nanocomposite nickel ceria cermet with low nickel content for anode-supported SOFCs

被引:26
|
作者
Jasinski, P [1 ]
Suzuki, T
Petrovsky, V
Anderson, HU
机构
[1] Gdansk Univ Technol, Dept Biomed Engn, Gdansk, Poland
[2] Univ Missouri, EMARC, Rolla, MO 65409 USA
来源
ELECTROCHEMICAL AND SOLID STATE LETTERS | 2005年 / 8卷 / 04期
关键词
D O I
10.1149/1.1869153
中图分类号
O646 [电化学、电解、磁化学];
学科分类号
081704 ;
摘要
Ni-ceria cermets with 7.5, 11, and 14 vol % of Ni manufactured by a novel method, called net-shape technology, are presented and evaluated. The method is a combination of conventional ceramic sintering and a polymer precursor impregnation technique. Ceria powder with a carbon pore former is sintered, constructing a rigid and stable oxide skeleton, which is next backfilled with Ni polymer precursor. The electrical conductivity of the cermets as a function of Ni content has been investigated. (C) 2005 The Electrochemical Society.
引用
收藏
页码:A219 / A221
页数:3
相关论文
共 50 条
  • [41] Anode-supported micro-tubular SOFCs made by aqueous electrophoretic deposition
    Cherng, J. S.
    Ho, M. Y.
    Yeh, T. H.
    Chen, W. H.
    [J]. CERAMICS INTERNATIONAL, 2012, 38 : S477 - S480
  • [42] Fuel composition and diluent effect on gas transport and performance of anode-supported SOFCs
    Jiang, Y
    Virkar, AV
    [J]. JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 2003, 150 (07) : A942 - A951
  • [43] Synthesis of nickel nanoparticles supported on hollow samaria-doped ceria particles via the solution-spray plasma technique: Anode catalysts for SOFCs
    Nishida, Ryuta
    Kakinuma, Katsuyoshi
    Nishino, Hanako
    Kamino, Takeo
    Yamashita, Hisao
    Watanabe, Masahiro
    Uchida, Hiroyuki
    [J]. SOLID STATE IONICS, 2009, 180 (14-16) : 968 - 972
  • [44] Pore structure improvement in cermet for anode-supported protonic ceramic fuel cells
    Park, Yu-Eun
    Ji, Ho-Il
    Kim, Byung-Kook
    Lee, Jong-Ho
    Lee, Hae-Weon
    Park, Jong-Sung
    [J]. CERAMICS INTERNATIONAL, 2013, 39 (03) : 2581 - 2587
  • [45] Improvement of electrochemical performance of anode-supported SOFCs by NiO-Ce0.9Gd0.1O1.95 nanocomposite powders
    Ding, Changsheng
    Lin, Hongfei
    Sato, Kazuhisa
    Kawada, Tatsuya
    Mizusaki, Junichiro
    Hashida, Toshiyuki
    [J]. SOLID STATE IONICS, 2010, 181 (25-26) : 1238 - 1243
  • [46] Low temperature anode-supported solid oxide fuel cells based on gadolinium doped ceria electrolytes
    Pinol, S.
    Morales, M.
    Espiell, F.
    [J]. JOURNAL OF POWER SOURCES, 2007, 169 (01) : 2 - 8
  • [47] Scale Up and Anode Development for La-Doped SrTiO3 Anode-Supported SOFCs
    Savaniu, Cristian-Daniel
    Miller, David N.
    Irvine, John T. S.
    [J]. JOURNAL OF THE AMERICAN CERAMIC SOCIETY, 2013, 96 (06) : 1718 - 1723
  • [48] The effect of porosity gradient in a Nickel/Yttria Stabilized Zirconia anode for an anode-supported planar solid oxide fuel cell
    An, Chung Min
    Song, Jung-Hoon
    Kang, Inyong
    Sammes, Nigel
    [J]. JOURNAL OF POWER SOURCES, 2010, 195 (03) : 821 - 824
  • [49] Graphene Incorporated Nanocomposite Anode for Low Temperature SOFCs
    Khalil Ahmad
    M. Ashfaq Ahmad
    Rizwan Raza
    M. Ajaml Khan
    Zohaib Ur Rehman
    Ghazanfar Abbas
    [J]. Journal of Electronic Materials, 2019, 48 : 7507 - 7514
  • [50] Graphene Incorporated Nanocomposite Anode for Low Temperature SOFCs
    Ahmad, Khalil
    Ahmad, M. Ashfaq
    Raza, Rizwan
    Khan, M. Ajaml
    Rehman, Zohaib Ur
    Abbas, Ghazanfar
    [J]. JOURNAL OF ELECTRONIC MATERIALS, 2019, 48 (11) : 7507 - 7514
12345