Redox behavior and transport properties of brownmillerite Ca-2(Fe,M)(2)O-5 +/-delta (M = Mn, Co)

abstract

Thermogravimetric and Mossbauer spectroscopy studies of brownmillerite-type Ca2Fe1.6M0.4O5 +/-delta (M = Mn Fe and Co) showed that the dominant oxidation states of transition metal cations at low temperatures are Mn4+, Fe3+ and Co3+. Doping with cobalt was found to increase the total conductivity at temperatures above 600 K, to decrease average thermal expansion coefficients from (11-13) x 10(-6) K-1 down to (7-11) x 10(-6) K-1 at 300-1270 K. and to promote reductive decomposition at moderate oxygen pressures. Although the effects of Mn substitution on the conductivity and thermal expansion of calcium ferrite are opposite, this donor-type doping also leads to lower phase stability. The oxygen partial pressure dependencies of the total conductivity and Seebeck coefficient of Ca2Fe1.6M0.4O5 +/-delta under oxidizing conditions indicate that the electronic transport is governed by p-type charge carriers irrespective of the oxygen nonstoichiometry level, suggesting important roles of iron disproportionation and localization of Mn4+ and Fe2+ states. On reduction, undoped Ca2Fe2O5-delta exhibits a transition to the n-type electronic conduction and minor segregation of CaO. The corresponding variations of the oxygen deficiency, measured by coulometric titration in combination with thermogravimetry, can be described by defect models assuming that the anion vacancy formation and Fe2+ localization occur in the perovskite-like octahedral and tetrahedral layers of the brownmillerite structure, respectively. (C) 2011 Elsevier B.V. All rights reserved.

keywords

ELECTRICAL-CONDUCTIVITY; OXYGEN NONSTOICHIOMETRY; CERAMIC MEMBRANES; ION MIGRATION; STABILITY; PEROVSKITES; CA2FE2O5; DEFECTS; OXIDES

subject category

Chemistry; Physics

authors

Shaula, AL; Markov, AA; Naumovich, EN; Waerenborgh, JC; Pivak, YV; Kharton, VV

our authors

Groups

Share this project:

Related Publications

We use cookies for marketing activities and to offer you a better experience. By clicking “Accept Cookies” you agree with our cookie policy. Read about how we use cookies by clicking "Privacy and Cookie Policy".