Magnetic damping in epitaxial Fe alloyed with low-atomic-number elements.

To develop low-moment, low-damping metallic ferromagnets for power-efficient spintronic devices, it is crucial to understand how magnetic relaxation is impacted by the addition of nonmagnetic elements. Here, we investigate magnetic relaxation (e.g., effective and intrinsic Gilbert damping) in epitaxial Fe films alloyed with light nonmagnetic elements of V and Al. By comparing Fe$_{100-x}$V$_{x}$ and Fe$_{100-x}$Al$_{x}$, we determine whether magnetic relaxation is lowered through the reduction of the average atomic number (i.e., atomic spin-orbit coupling) or the reduction of the density of states at the Fermi level $D(E_{F})$. We observe that FeV alloys exhibit lower damping compared to pure Fe, whereas damping in FeAl alloys increases with increasing Al content. Our experimental results combined with density functional theory calculations indicate that reducing $D(E_{F})$, rather than the average atomic number, has a more significant impact in lowering damping in Fe alloyed with light elements.