Temperature dependent anisotropy and linewidth in the high-Q ferrimagnet V(TCNE)x

The search for low-loss magnetic materials, traditionally driven by applications in microwave electronics, has gained new urgency and additional constraints from emerging applications in quantum information science and technology. While yttrium iron garnet (YIG) has been the material of choice for decades, the emergence of molecule-based materials with robust magnetism and ultra-low damping has opened new avenues for exploration. Specifically, thin films of vanadium tetracyanoethylene (V(TCNE)x) have shown room temperature Gilbert damping that rivals the intrinsic (bulk) damping of polished YIG spheres (alpha = 4 x 10^-5). Here, we present the first systematic study of the low-temperature regime for V(TCNE)x thin films, revealing a temperature-drive strain dependent magnetic anisotropy that compensates the thin film shape anisotropy, and the recovery of magnetic resonance linewidth at 5 K comparable to room temperature values (roughly 2 G at 9.86 GHz). We can account for the variations of the V(TCNE)x linewidth within the context of the varying magnetic anisotropy and see no signature of scattering from paramagnetic impurities.