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A numerical study of infiltrated solid oxide fuel cell electrode with dual‐phase backbone
Author(s) -
Wan Shuaibin,
Yan Mufu,
Zhang Yanxiang
Publication year - 2018
Publication title -
international journal of energy research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.808
H-Index - 95
eISSN - 1099-114X
pISSN - 0363-907X
DOI - 10.1002/er.4129
Subject(s) - materials science , yttria stabilized zirconia , electrode , solid oxide fuel cell , composite number , composite material , infiltration (hvac) , oxide , microstructure , cubic zirconia , triple phase boundary , percolation threshold , porosity , conductivity , lanthanum manganite , chemical engineering , electrical resistivity and conductivity , electrolyte , ceramic , chemistry , electrical engineering , metallurgy , engineering
Summary Three‐dimensional microstructure of infiltrated solid oxide fuel cell electrodes with dual‐phase backbone is simulated numerically. This work employs LSM (lanthanum strontium manganite) infiltrated LSM yttria‐stabilized zirconia composite electrodes as an example. Important geometric properties, including percolation probability of LSM, total and percolated three‐phase boundary (TPB) lengths, and total and percolated surface areas of LSM, are calculated under various LSM nanoparticle loadings. One important finding is that compared with pure yttria‐stabilized zirconia backbone, dual‐phase backbone results in lower TPB length and has little impact on the surface area of LSM particles. Therefore, the addition of LSM backbone may be ineffective, even negative in promoting the electrode performance, however, can significantly reduce the LSM infiltration threshold loading to form a percolating network. The trade‐off between decreasing infiltration cycle and increasing TPB length demands an optimized content of LSM in backbone.