Influence of Yttrium(Y) on properties of Lanthanum Cobalt Oxides

Abstract

Many materials exhibit various types of phase transitions at different temperatures, with many also demonstrating polymorphism. Doping materials can significantly alter their conductivity. In light of this, we have investigated the electrical conductivity of LaCoO3, specifically its temperature dependence when doped with Yttrium (Y). The crystal structure of Lanthanum Yttrium Cobalt oxide (La1-xYx Co O3) adopts a perovskite form, characterized by the general stoichiometry ABX3, where A and B are cations, and X is an anion. This material undergoes a magnetic phase transition between 50-100 K, a structural phase transition between 100-300 K, and an insulator-to-metal transition at 500 K. At room temperature, LaCoO3 exhibits polaron-type hopping conduction. Our aim was to understand the electrical conductivity at 300 K and how it varies with temperature when La3+ is replaced by Y3+. The electrical properties of the perovskite crystal are consistent with small polaron hopping conduction, which theoretically follows Mott's variable range hopping model, where conductivity obeys an exponential law, and resistivity follows an inverse exponential pattern. In this work, we compare the experimental resistivity graph with the theoretical inverse of the conductivity graph, showing that our experimental results align with the polaron hopping conduction model within a certain range. Additionally, the experiment confirms polymorphism in various cases. We observed that increasing the concentration of Y3+ enhances the metallic properties of La1-x Yx Co O3, and we found a significant correlation between conductivity and symmetry. Furthermore, the study highlights the material's phase transitions and polymorphic behavior.