Observation of correlation induced metal to half-metal phase transition and large orbital moment in Sr2CoO4

Abstract

We present a detailed mean-field study to address the fundamental discrepancy in the ground state magnetization of Sr2CoO4 (SCO). In contrast to the ferromagnetic metallic ground state obtained from density functional theory (DFT), DFT+U gives three ferromagnetic solutions converging to integer moment values (1, 2 \& 3 μB/f.u) over a range of U. Interestingly, two of the solutions are found to exhibit half-metallicity with correspondingly S=1/2 and S=3/2 spin states. The half-metallic ferromagnetic state with S=3/2 is found to be the ground state solution for SCO. Co atoms show a large deviation from the formal +4 oxidation state indicating the presence of strong covalency effects. Our results suggest a plausible metal to half-metal phase transition around U(J)=4.4(1.16) eV. The Fermi surface study shows gradual collapse in states leading to half-metallicity suggesting k-dependence of effective U around the critical region. Surprisingly, in the presence of spin-orbit coupling (SOC), unexpectedly large orbital moment (Lz=0.6) is noted in SCO putting it among the class of 3d based transition metal compounds exhibiting pronounced orbital magnetization. The calculations give large magnetocrystalline anisotropy energy (MAE) of 48 meV. Large values of orbital magnetic moment contribution and MAE, in the presence of strong correlation effects, provide a better interpretation of experimental magnetization observed in SCO.