Magnetization-Tunable Topological Phase Transitions in Ferromagnetic Kagome Monolayers of Co3X3Y2 (X=Sn,Pb; Y=S,Se)

Abstract

The quantum anomalous Hall effect in magnetic kagome materials has emerged as a versatile platform for dissipationless electronic and spintronic devices. In this work, we demonstrate that the orientation of magnetic moments m(θ,φ) at lattice sites provides a practical tuning mechanism for engineering nontrivial topological phases in monolayer kagome ferromagnets. To elucidate the mechanism, we construct a symmetry-adapted minimal tight-binding model for kagome ferromagnets that includes intrinsic spin-orbit coupling (SOC) and the intrinsic Rashba SOC permitted by broken out-of-plane mirror symmetry between nearest-neighbor kagome sites and can capture the resulting topological phase diagram as a function of m(θ,φ). In particular, the restoration of in-plane mirror symmetry for specific values of φ drives a topological phase transition upon varying the in-plane orientation of the moments m(θ = 90, φ). In contrast, for fixed φ, the transitions driven by varying θ originate from the competition between Rashba SOC and intrinsic SOC. Density functional theory calculations for ferromagnetic kagome monolayers belonging to the Co3X3Y2 family (X=Sn,Pb; Y=S,Se) support the predictions of the proposed minimal tight-binding model. These findings provide design guidelines for tunable topological phases in kagome materials.

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