Ligand-SOC enhanced 4f5 Kitaev antiferromagnet: Application to SmI3

Abstract

The search for Kitaev quantum spin liquids (Kitaev-QSLs) in real materials has mainly focused on 4d- and 5d-electron honeycomb systems. A recent experimental study on the 4f5 honeycomb iodide SmI3 reported the absence of long-range magnetic order down to 0.1\ K, suggesting a possible Kitaev-QSL phase. Motivated by the interplay between the complex exchange processes inherent to the 4f5 multi-electron configuration and the strong spin-orbit coupling (SOC) of the iodine ligands, we systematically investigate the effective exchange interactions in SmI3 using the strong coupling expansion method. Our findings reveal that bond-dependent SOCs (bond-SOCs), extracted from relativistic density functional theory (DFT) calculations, significantly enhance the antiferromagnetic (AFM) Kitaev interaction, driving the system close to the AFM Kitaev point. A microscopic analysis based on the Slater-Koster approach further indicates that the strong SOC of the iodine ligands (ligand-SOC) is the origin of bond-SOCs and plays a pivotal role in mediating the superexchange processes. Additionally, we identify a spin-flop transition induced by the bond-SOCs, where the enhanced AFM Kitaev interactions shift the AFM order from the out-of-plane [1, 1, 1]-direction to an in-plane orientation, breaking the C3 rotational symmetry. Linear spin-wave theory (LSWT) further predicts the emergence of gapless modes following the spin-flop transition, indicating enhanced fluctuations and increased instability near the AFM Kitaev point. Our results highlight the crucial role of strong ligand-SOC in stabilizing the dominant AFM Kitaev interactions in SmI3 and provide valuable insights for discovering new f-electron Kitaev-QSL candidates.