Oxygen Mobility in the Materials for Solid Oxide Fuel Cells and Catalytic Membranes (Review) | Sciact - CRIS-system of Boreskov Institute of Catalysis

Oxygen Mobility in the Materials for Solid Oxide Fuel Cells and Catalytic Membranes (Review) Review

Journal

Russian Journal of Electrochemistry
ISSN: 1023-1935 , E-ISSN: 1608-3342

Output data

Year: 2019, Volume: 55, Number: 8, Pages: 701-718 Pages count : 8 DOI: 10.1134/S1023193519080147

Funding (5)

1	Russian Science Foundation	16-13-00112
2	Federal Agency for Scientific Organizations	0303-2016-0013
3	Federal Agency for Scientific Organizations	0052-2014-0011 (АААА-А17-111711600093-8)
4	Russian Foundation for Basic Research	16-03-00143 (АААА-А16-116031050045-0)
5	Russian Foundation for Basic Research	18-38-20063 (АААА-А18-118102390007-8)

Oxygen transport (including oxygen mobility and surface reactivity) is one of the important factors governing electrochemical activity of solid oxide fuel cells electrodes as well as oxygen and hydrogen separation membranes based on materials with mixed oxide-ionic and electronic conductivity. In this work, oxygen mobility data obtained for a series of materials destined for such devices using modern techniques of oxygen isotope heteroexchange are summarized. Series of solid oxide fuel cells’ and membranes’ materials were studied by isotope exchange of their oxygen with 18O2 and C18O2 in isothermal and temperature-programmed modes using closed and flow reactors and data analysis based on developed model of oxygen diffusion and exchange. For solid electrolytes’ materials (Sc- and Ce-doped zirconia) as well as for proton-conducting materials [Ln5.5(Mo,W)O11.25], the effect of composition heterogeneity on the oxygen mobility was demonstrated. For Ln6 – xWO12 – δ, a strong effect of structure on the oxygen mobility was demonstrated. For oxides with asymmetric structure, where oxygen migration proceeds via cooperative mechanisms [La2(Mo,W)2O9, (Ln,Ca)2NiO4], the doping hampers the cooperative migration, resulting in oxygen mobility deterioration and sometimes forming additional slow diffusion channels. In the PrNi0.5Co0.5O3–Ce0.9Y0.1O2 nanocomposites that are materials of the solid oxide fuel cells’ cathode and functional layer of the oxygen separation membranes, two diffusion channels were observed, where more mobile oxygen corresponds to the fluorite phase and interfaces; less mobile, to the perovskite phase. This is due to special features of cations redistribution between the phases.

Sadykov V.A. , Sadovskaya E.M. , Eremeev N.F. , Skriabin P.I. , Krasnov A.V. , Bespalko Y.N. , Pavlova S.N. , Fedorova Y.E. , Pikalova E.Y. , Shlyakhtina A.V.
Oxygen Mobility in the Materials for Solid Oxide Fuel Cells and Catalytic Membranes (Review)
Russian Journal of Electrochemistry. 2019. V.55. N8. P.701-718. DOI: 10.1134/S1023193519080147 WOS Scopus РИНЦ AN OpenAlex

Садыков В.А. , Садовская Е.М. , Еремеев Н.Ф. , Скрябин П.И. , Краснов А.В. , Беспалко Ю.Н. , Павлова С.Н. , Федорова Ю.Е. , Пикалова Е.Ю. , Шляхтина А.В.
Подвижность кислорода материалов твердооксидных топливных элементов и каталитических мембран (обзор)
Электрохимия. 2019. Т.55. №8. С.899-918. DOI: 10.1134/S0424857019080140 РИНЦ OpenAlex

Submitted:	Nov 29, 2018
Accepted:	Mar 12, 2019
Published print:	Aug 1, 2019
Published online:	Sep 23, 2019

Web of science:	WOS:000487550800001
Scopus:	2-s2.0-85073055069
Elibrary:	41678671
Chemical Abstracts:	2019:1825299
OpenAlex:	W2975491043

DB	Citing
Web of science	24
Scopus	26
Elibrary	23
OpenAlex	28