Abstract
Recently, an oxide with K2NiF4 structure but free of transition metals was developed with the intent of creating a new solid electrolyte material. Here, the original composition, La1.6+xSr0.4−xAl0.4Mg0.6O4+x/2, was modified by replacing Sr, Al, or Mg, with the isovalent substitutes Ca, Ga, or Zn, respectively. The phase stability of these compounds was investigated to determine, specifically, the maximum concentration of oxygen defects allowed by the crystal structure. It was found that a greater concentration of oxygen vacancy defects than interstitials could be created in all of the compositions. In addition, the influence of the cation substitutions on the lattice parameters and the electrical conduction behavior was analyzed. At 650 °C in air, the highest conductivity achieved for B-site substituted compositions was 2.63 × 10−4 S cm−1 in La1.5Sr0.5Al0.4Zn0.6O3.9, much higher than 5.82 × 10−7 S cm−1 in La1.65Sr0.35Al0.4Mg0.6O4.025, while the highest value for A-site substituted compositions was only 7.55 × 10−7 S cm−1 in La1.65Ca0.35Al0.4Mg0.6O4.025. The electrochemical results indicated that A-site substituted compositions, although with low conductivity, were possible oxygen ion conductors, while B-site substituted compositions exhibited either mixed ionic and hole conductivity or pure hole conductivity.
Highlights
Solid oxide fuel cells (SOFCs) are a promising alternative power generation source with an electrolyte that is a ceramic conductor of oxygen ions
Compared to proton exchange membrane fuel cells (PEMFCs) and alkaline fuel cells (AFCs), which are typically limited in the choice of operational fuel, SOFCs can make use of a wide variety of fuels including hydrogen, hydrocarbons, alcohols, and other alternatives.[1,2]
La1.6+xSr0.4ÀxGa0.4Mg0.6O4+x/2 (À0.1 # x # 0), La1.6+xSr0.4ÀxAl0.4Zn0.6O4+x/2 (À0.2 # x # +0.05) and La1.6+xCa0.4ÀxAl0.4Mg0.6O4+x/2 (À0.2 # x # +0.05) with K2NiF4 structures were synthesized without impurity phases
Summary
Solid oxide fuel cells (SOFCs) are a promising alternative power generation source with an electrolyte that is a ceramic conductor of oxygen ions. Materials with the cubic uorite crystal structure, such as doped zirconia and ceria, are the conventional electrolyte materials for SOFCs.[6,7,8,9] More recently, (La, Sr)(Ga, Mg)O3Àd (LSGM) with a perovskite structure has been developed as a solid electrolyte with high ionic conductivity,[10,11,12,13] and materials with more exotic crystal structures are being actively explored too.[14,15,16,17]. Zn is examined in the interest of increasing the cell volume to promote ion mobility.[27,28] Of speci c interest is whether these substitutions are able to increase oxygen defect mobility and/or increase available defect concentrations by allowing increased P-layer/R-layer charge separation with nominal compositions beyond (A3+1.6A2+0.4)(B3+0.4B2+0.6)O4
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