Coherent phonon and unconventional carriers in the magnetic kagome metal Fe3Sn2

Abstract

Temperature- and fluence-dependent carrier dynamics of the magnetic Kagome metal Fe3Sn2 were studied using the ultrafast optical pump-probe technique. Two carrier relaxation processes (τ1 and τ2) and a laser induced coherent optical phonon were observed. By using the two-temperature model for metals, we ascribe the shorter relaxation τ1 (~1 ps) to hot electrons transferring their energy to the crystal lattice via electron-phonon scattering. τ2 (~25 ps), on the other hand, cannot be explained as a conventional process and is attributed to the unconventional (localized) carriers in the material. The observed coherent oscillation is assigned to be a totally symmetric A1g optical phonon dominated by Sn displacements out of the Kagome planes, and possesses a prominently large amplitude, on the order of 10-3, comparable to the maximum of the reflectivity change (/R). This amplitude is equivalent to charge-density-wave (CDW) systems, although no signs of such an instability were hitherto reported in Fe3Sn2. Our results set an unexpected connection between Fe3Sn2 and kagome metals with CDW instabilities, and suggest a unique interplay between phonon and electron dynamics in this compound.