Chiral electronic excitations and strong electron-phonon coupling to Weyl fermions in the Kagome semimetal Co3Sn2S2

Abstract

We present results of a Raman scattering study of the Kagome ferromagnet Co3Sn2S2, with a focus on electronic and phononic excitations and their interplay. We provide a theoretical analysis of the electronic band structure, enabling a semi-quantitative explanation of the spectra. A prominent feature in the electronic spectra is a redistribution of spectral weight from low to high energies in all polarization configurations starting at the Curie temperature TC. In the symmetry-resolved spectra, the suppression of the A1g continuum in the ferromagnetic state arises from the redistribution of electronic states below TC, while a strong enhancement of the A2g continuum is linked to the dynamics of fermions near the Fermi level E F being characterized by spin-momentum locking near Weyl points. The A1g phonon modulates the position of these Weyl points and couples strongly to the related fermions close to E F. These results allow a comprehensive understanding of the bulk band structure evolution as a function of temperature in Co3Sn2S2, offering key insights for further studies of the driving force behind the long-range magnetic order and novel topological states in this compound.