Spin Frustration and Magnetic Exchange in Cobalt Aluminum Oxide Spinels

Abstract

We report on x-ray diffraction, magnetic susceptibility, electron- spin resonance and heat- capacity studies of Co[Al1-xCox]2O4 for Co concentrations 0<x<1. In this spinel system only the A-site Co2+ cation is magnetic, while the non-magnetic B-site Al3+ is substituted by the low-spin non-magnetic Co3+, and it is possible to investigate the complete phase diagram from Co2+Al3+2O4 to Co2+Co3+2O4. All samples reveal large negative Curie-Weiss temperatures ThetaCW of the order of -110 K independent of concentration, which is attributed to a high multiplicity of the superexchange interactions between the A-site Co2+ cations. A pure antiferromagnetic state is found for x = 1.0 and 0.9 with Neel temperatures TN = 29.5 K and 21.2 K, respectively, as evidenced by lambda-like anomalies in the specific heat. Compositions with 0.3<x<0.75 show smeared out strongly reduced magnetic ordering temperatures. At low temperatures, a T2.5 dependence of the specific heat is indicative of a spin-liquid state. For x < 0.2 a T2 dependence of the specific heat and a spin-glass like behavior of the susceptibility below Tf = 4.7 K are observed. The high value of the frustration parameter f = |ThetaCW|/Tf > 10 indicates the presence of strong spin frustration at least for x < 0.6. The frustration mechanism is attributed to competing nearest neighbor and next-nearest neighbor superexchange interactions between the A-site Co2+ ions.