Contrasting the magnetism in La2-xSrxFeCoO6 (x = 0, 1, 2) double perovskites: the role of electronic and cationic disorder

Abstract

The magnetism of the double perovskite compounds \ (x = 0, 1, 2) are contrasted using magnetization, neutron diffraction and electron paramagnetic resonance with the support from density functional theory calculations. \ is identified as a long-range ordered antiferromagnet displaying a near-room temperature transition at TN = 270~K, accompanied by a low temperature structural phase transition at TS = 200~K. The structural phase transformation at TS occurs from R3c at 300~K to Pnma at 200~K. The density functional theory calculations support an insulating non-compensated AFM structure. The long-range ordered magnetism of \ transforms to short-range glassy magnetism as La is replaced with Sr in the other two compounds. The magnetism of \ is differentiated from the non-equilibrium glassy features of \ and \ using the cooling-and-heating-in-unequal-fields (CHUF) magnetization protocols. This contransting magnetism in the \ series is evidenced in electron paramegnetic resonance studies. The electronic density-of-states estimated using the density functional theory calculations contrast the insulating feature of \ from the metallic nature of . From the present suite of experimental and computational results on , it emerges that the electronic degrees of freedom, along with antisite disorder, play an important role in controlling the magnetism observed in double perovskites.