Ultrafast element- and depth-resolved magnetization dynamics probed by transverse magneto-optical Kerr effect spectroscopy in the soft x-ray range

We report on time- and angle-resolved transverse magneto-optical Kerr effect spectroscopy in the soft x-ray range that, by analysis via polarization-dependent magnetic scattering simulations, allows to determine the spatio-temporal and element-specific evolution of femtosecond laser-induced spin dynamics in nanostructured magnetic materials. We demonstrate this ability on a ferrimagnetic GdFe film enclosed by Ta and Pt cap and seed layers, revealing a depth-dependent de- and remagnetization within the GdFe layer due to a thermal gradient at the buried seed interface, induced by strongly layer-dependent photoexcitation. Our work provides a quantitative insight into light-driven spin dynamics occurring at buried interfaces of complex magnetic heterostructures, which can be tailored and functionalized for future opto-spintronic devices.