Research output: Contribution to journal › Conference article › peer-review
Design of materials for solid oxide fuel cells cathodes and oxygen separation membranes based on fundamental studies of their oxygen mobility and surface reactivity. / Sadykov, Vladislav; Sadovskaya, Ekaterina; Eremeev, Nikita et al.
In: E3S Web of Conferences, Vol. 116, 00068, 24.09.2019.Research output: Contribution to journal › Conference article › peer-review
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TY - JOUR
T1 - Design of materials for solid oxide fuel cells cathodes and oxygen separation membranes based on fundamental studies of their oxygen mobility and surface reactivity
AU - Sadykov, Vladislav
AU - Sadovskaya, Ekaterina
AU - Eremeev, Nikita
AU - Pikalova, Elena
AU - Bogdanovich, Nina
AU - Filonova, Elena
AU - Fedorova, Yulia
AU - Krasnov, Alexey
AU - Skriabin, Pavel
AU - Lukashevich, Anton
PY - 2019/9/24
Y1 - 2019/9/24
N2 - Design of materials for solid oxide fuel cells cathodes and oxygen separation membranes and studying their oxygen transport characteristics are important problems of modern hydrogen energy. In the current work, fundamentals of such materials design based on characterization of their oxygen mobility by oxygen isotope exchange with C18O2 and 18O2 in flow and closed reactors for samples of Ruddlesden - Popper-type oxides Ln2-xCaxNiO4+δ, perovskite-fluorite nanocomposites PrNi0.5Co0.5O3-δ - Ce0.9Y0.1O2-δ, etc. are presented. Fast oxygen transport was demonstrated for PNC - YDC (DO ~10-8 cm2/s at 700°C) nanocomposites due to domination of the fast diffusion channel involving oxygen of the fluorite phase with incorporated Pr cations and developed perovskite-fluorite interfaces. For LnCNO materials a high oxygen mobility (DO ~10-7 cm2/s at 700°C) provided by the cooperative mechanism of its migration was demonstrated. Depending on Ca dopant content and Ln cation nature, in some cases 1-2 additional channels of the slow diffusion appear due to decreasing the interstitial oxygen content and increasing the energy barrier for oxygen jumps due to cationic size effect. Optimized by the chemical composition and nanodomain structure materials of these types demonstrated a high performance as SOFC cathodes and functional layers in asymmetric supported oxygen separation membranes.
AB - Design of materials for solid oxide fuel cells cathodes and oxygen separation membranes and studying their oxygen transport characteristics are important problems of modern hydrogen energy. In the current work, fundamentals of such materials design based on characterization of their oxygen mobility by oxygen isotope exchange with C18O2 and 18O2 in flow and closed reactors for samples of Ruddlesden - Popper-type oxides Ln2-xCaxNiO4+δ, perovskite-fluorite nanocomposites PrNi0.5Co0.5O3-δ - Ce0.9Y0.1O2-δ, etc. are presented. Fast oxygen transport was demonstrated for PNC - YDC (DO ~10-8 cm2/s at 700°C) nanocomposites due to domination of the fast diffusion channel involving oxygen of the fluorite phase with incorporated Pr cations and developed perovskite-fluorite interfaces. For LnCNO materials a high oxygen mobility (DO ~10-7 cm2/s at 700°C) provided by the cooperative mechanism of its migration was demonstrated. Depending on Ca dopant content and Ln cation nature, in some cases 1-2 additional channels of the slow diffusion appear due to decreasing the interstitial oxygen content and increasing the energy barrier for oxygen jumps due to cationic size effect. Optimized by the chemical composition and nanodomain structure materials of these types demonstrated a high performance as SOFC cathodes and functional layers in asymmetric supported oxygen separation membranes.
UR - http://www.scopus.com/inward/record.url?scp=85072797521&partnerID=8YFLogxK
U2 - 10.1051/e3sconf/201911600068
DO - 10.1051/e3sconf/201911600068
M3 - Conference article
AN - SCOPUS:85072797521
VL - 116
JO - E3S Web of Conferences
JF - E3S Web of Conferences
SN - 2555-0403
M1 - 00068
T2 - 2019 International Conference on Advances in Energy Systems and Environmental Engineering, ASEE 2019
Y2 - 9 June 2019 through 12 June 2019
ER -
ID: 21792213