Competing itinerant and local spin interactions in kagome metal FeGe

TL;DR

This study reveals complex magnetic excitations in kagome metal FeGe, showing how competing itinerant and local spin interactions lead to diverse quantum phases and are influenced by Fermi surface nesting and electron correlations.

Contribution

The paper demonstrates the coexistence of incommensurate and commensurate spin excitations in FeGe, linking them to Fermi surface nesting and charge density wave order through neutron scattering and DFT calculations.

Findings

Incommensurate spin excitations appear above T_Canting and merge into gapped spin waves.

Incommensurate excitations deviate from Bose population, indicating critical scattering.

Coupling between spin density wave and charge density wave is suggested by temperature dependence.

Abstract

Two-dimensional kagome metals consisting of corner-sharing triangles offer a unique platform for studying strong electron correlations and band topology due to its geometrically frustrated lattice structure. The similar energy scales between spin, lattice, and electronic degrees of freedom in these systems give rise to competing quantum phases such as charge density wave (CDW), magnetic order, and superconductivity. For example, kagome metal FeGe first exhibits A-type collinear antiferromagnetic (AFM) order at T_N ~ 400 K, then establishes a CDW phase coupled with AFM ordered moment below T_CDW ~ 100 K, and finally forms a $c$-axis double cone AFM structure around T_Canting ~ 60 K. Here we use neutron scattering to demonstrate the presence of gapless incommensurate spin excitations associated with the double cone AFM structure at temperatures well above T_Canting and T_CDW that merge into gapped commensurate spin waves from the A-type AFM order. While commensurate spin waves follow the Bose population factor and can be well described by a local moment Heisenberg Hamiltonian, the incommensurate spin excitations first appear below T_N where AFM order is commensurate, start to deviate from the Bose population factor around T_CDW, and peaks at T_Canting, consistent with a critical scattering of a second order magnetic phase transition, as a function of decreasing temperature. By comparing these results with density functional theory calculations, we conclude that the incommensurate magnetic structure arises from the nested Fermi surfaces of itinerant electrons and the formation of a spin density wave order. The temperature dependence of the incommensurate spin excitations suggests a coupling between spin density wave and CDW order, likely due to flat electronic bands near the Fermi level around T_N and associated electron correlation effects.