Influence of global and local distortion on magnetic properties of cubic La0.6Ba0.4–xCaxCoO3

Abstract

The magnetic and structural study of the La0.6Ba0.4–xCaxCoO3 (x=0.0, 0.1, 0.2, 0.3, and 0.4) compounds with the lowest global or local distortion are studied. The compounds with x=0, 0.1, 0.2 and 0.3 is crystallized in the structure with the space group Pm-3m, and that with x=0.4 is Pnma. A ferromagnetic-like transition is observed and the Curie temperature, ranging from 235K to 220K, decreases slightly with the increasing Ca2+ content for x≤0.3, and the transition temperature is as low as 175K with x=0.4. A hump, with the hump temperature slightly increase with the Ca2+ content, is observed in the thermal magnetization curves of all of the compounds at the ZFC state, and it is owing to the magnetic frustration because of the coexistence of the FM and the AFM interaction. Above the transition temperature, the magnetic susceptibility versus the temperature is fitted with the ferromagnetic Curie–Weiss law for the compounds with x≤0.3, and that with x=0.4 coincides with the ferrimagnetic Weiss-mean-field model. The absolute values of the exchange constants J1 in the compounds with x≤0.3 and those of JCO3+CO3+,JCO3+CO4+,JCO4+CO4+ of La0.6Ca0.4CoO3 are deduced from the fitting. The results indicate that (i) the ferromagnetic exchange constants J1 increases with the Ca2+ content x≤0.3; (ii) the ferromagnetic interaction, JCo3+Co4+, plays a main role in the magnetic properties of La0.6Ca0.4CoO3; (iii) the antiferromagnetic interactions, JCo3+Co3+, JCo4+Co4+, are not negligible in the compound x=0.4. The unsaturated magnetization at 70kOe and the high coercive field in the hysteretic magnetization curve supports the existence of the antiferromagnetic interaction, and the percentage of the antiferromagnetic domain is calculated.