Magnetism and Spin Dynamics in Room-Temperature van der Waals Magnet Fe$_5$GeTe$_2$

Two-dimensional (2D) van der Waals (vdWs) materials have gathered a lot of attention recently. However, the majority of these materials have Curie temperatures that are well below room temperature, making it challenging to incorporate them into device applications. In this work, we synthesized a room-temperature 2D magnetic crystal Fe$_5$GeTe$_2$ with a Curie temperature $T_c$ = 332 K, and studied its magnetic properties by vibrating sample magnetometry (VSM) and broadband ferromagnetic resonance (FMR) spectroscopy. The experiments were performed with external magnetic fields applied along the $c$-axis ($H\parallel c$) and the $ab$-plane ($H\parallel ab$), with temperatures ranging from 300 K to 10 K. We have found a sizable Lande $g$-factor difference between the $H\parallel c$ and $H\parallel ab$ cases. In both cases, the Lande $g$-factor values deviated from $g$ = 2. This indicates a possible contribution of orbital angular momentum to the magnetic moment but may also be caused by lack of saturation at FMR. The FMR measurements also show a broadened linewidth at low temperatures; together with the VSM data, our measurements indicate that magnetic domains of different orientations develop within Fe$_5$GeTe$_2$ in both $H\parallel ab$ and $H\parallel c$ cases, with a higher level of randomness in the $H\parallel c$ case, especially at lower temperatures. Our experiments highlight key information regarding the magnetic state and spin scattering processes in Fe$_5$GeTe$_2$, which promote the understanding of magnetism in Fe$_5$GeTe$_2$, leading to implementations of Fe$_5$GeTe$_2$ based room-temperature spintronic devices.