The role of spin-lattice coupling for ultrafast magnetization changes in rare earth metals

TL;DR

This study compares femtosecond laser-induced spin dynamics in Gd and Tb, revealing how differences in spin-lattice coupling influence ultrafast demagnetization and optical switching in rare earth metals.

Contribution

It demonstrates the distinct roles of weak and strong 4f spin-lattice coupling in Gd and Tb, linking these interactions to ultrafast magnetic behavior.

Findings

Gd exhibits a 15 ps spin polarization decay, Tb shows 400 fs decay.

Similar exchange splitting dynamics in Gd and Tb despite different decay times.

Lattice acts mainly as heat sink in Gd, but influences demagnetization in Tb.

Abstract

By comparing femtosecond laser-pulse-induced spin dynamics in the surface state of the rare earth metals Gd and Tb we show that the spin polarization of the valence states in both materials decays with significantly different time constants of 15\,ps and 400\,fs, respectively. The distinct spin polarization dynamics in Gd and Tb are opposed by similar exchange splitting dynamics in the two materials. The different time scales observed in our experiment can be attributed to weak and strong $4f$ spin to lattice coupling in Gd and Tb suggesting an intimate coupling of spin polarization and 4f magnetic moment. While in Gd the lattice mainly acts as a heat sink, it contributes significantly to ultrafast demagnetization of Tb. This helps explain why all optical switching is observed in FeGd -- but rarely in FeTb-based compounds.