Competing Magnetic Phases in Li-Fe-Ge Kagome Systems

Abstract

Competing interlayer magnetic interactions in kagome magnets can lead to diverse magnetic phases, which enable various promising topological or quantum material properties. Here, the electronic structure and magnetic properties have been studied using first-principles calculations for the LiFe6Ge6, LiFe6Ge4, and LiFe6Ge5 compounds sharing the kagome Fe3Ge layer motif but with different interlayer arrangements. For LiFe6Ge4 and LiFe6Ge5, the predicted magnetic ground states are collinear antiferromagnetic (AFM) states involving a mix of ferromagnetic (FM) and AFM interlayer orientations. Whereas for LiFe6Ge6, an incommensurate cycloidal spin spiral is stabilized as a ground state, being close to a collinear A-type AFM state. The analysis of magnetic RKKY exchange coupling confirms the results of electronic structure calculations. The values of atomic magnetic moments are in good agreement with existing experimental estimations. Our experiments on LiFe6Ge6 single crystals have observed AFM ordering at ~540 K and transition to another magnetic phase, with a small FM component (possibly with spin canting), below ~270 K. Thus, our theory and experiment suggest the existence and sequence of collinear and noncollinear magnetic states in kagome LiFe6Ge6. Our findings provide a platform for exploring various novel magnetic phases and associated unconventional or topological magnetism.