Oxygen permeability of Ln(1-x)M(x)CoO(3-delta) (Ln = La, Pr, Nd; M = S
r, Ca, Bi, Pb; x = 0-0.9) and SrCo(1-x)Me(x)O(3-delta) (Me = Cr, Mn, F
e, Ni, Cu; x = 0-0.5) perovskite-like oxide ceramics, which are promis
ing materials for high-temperature electrochemical oxygen membranes wh
ere matter is transferred owing to conjugate transport of oxide ions O
2- and electrons through a gas-tight ceramic material, has been invest
igated. Dependencies of the density of the molecular oxygen flow passi
ng through the membrane on the chemical potential gradient of O-2 in t
he gas phase and temperature have been analyzed. Physicochemical model
s of such dependencies are proposed. It is shown that complex oxides S
rCo1-xFexO3-delta (x = 0.2-0.35) and La1-xSrxCoO3-delta (x = 0.65-0.75
) having the highest oxide ionic conductivity can be used as materials
for electrochemical oxygen membranes.