Impact of spin-orbit coupling on the magnetism of Sr3MIrO6 (M = Ni, Co)

Abstract

Using density functional calculations, we demonstrate that the spin-orbit coupling (SOC) of the Ir4+ ion plays an essential role in determining the antiferromagnetism of the hexagonal spin-chain system Sr3MIrO6 (M = Ni, Co) by tuning the crystal-field level sequence and altering the Ir-M inter-orbital interactions. The SOC splits the e'g doublet of the octahedral Ir4+ ion (t2g5) in a trigonal crystal field, and the single t2g hole resides on the e'g upper branch and gives rise to the antiferromagnetic superexchange. In absence of the SOC, however, the single t2g hole would occupy the a1g singlet instead, which would mediate an unreal ferromagnetic exchange due to a direct a1g hopping along the Ir-M chain. We also find that the Ni2+ and Co2+ ions are both in a high-spin state and moreover the Co2+ ion carries a huge orbital moment. This work well accounts for the recent experiments and magnifies again the significance of the SOC in iridates.