We investigate the influence of spin currents during ultrafast laser-induced demagnetization of magnetic bilayer structures by a new all-optical method to measure material- and/or depth-resolved magnetization dynamics. By describing the magneto-optical response of the bilayers in the complex Kerr plane, it is shown that the material-specific magnetization dynamics of the individual layers can be measured by a marginal adjustment to any conventional time-resolved magneto-optical Kerr effect setup. We use this technique to trace superdiffusive spin currents in magnetic Ni/Fe bilayers, providing new insight on its importance to ultrafast laser-induced demagnetization
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...
We investigate the influence of spin currents during ultrafast laser-induced demagnetization of magn...
We investigate the influence of spin currents during ultrafast laser-induced demagnetization of magn...
We investigate the influence of spin currents during ultrafast laser-induced demagnetization of magn...
We investigate the influence of spin currents during ultrafast laser-induced demagnetization of magn...
This work explores laser-induced, element-selective, femtosecond spin dynamics in ferromagnetic laye...
The response of exchange coupled ferromagnet/antiferromagnet metallic bilayers to laser excitation d...
The response of exchange coupled ferromagnet/antiferromagnet metallic bilayers to laser excitation d...
Spin currents can be generated on an ultrafast time scale by excitation of a ferromagnetic (FM) thin...
Spin currents can be generated on an ultrafast time scale by excitation of a ferromagnetic (FM) thin...
Spin currents can be generated on an ultrafast time scale by excitation of a ferromagnetic (FM) thin...
Spin currents can be generated on an ultrafast time scale by excitation of a ferromagnetic (FM) thin...
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...
We investigate the influence of spin currents during ultrafast laser-induced demagnetization of magn...
We investigate the influence of spin currents during ultrafast laser-induced demagnetization of magn...
We investigate the influence of spin currents during ultrafast laser-induced demagnetization of magn...
We investigate the influence of spin currents during ultrafast laser-induced demagnetization of magn...
This work explores laser-induced, element-selective, femtosecond spin dynamics in ferromagnetic laye...
The response of exchange coupled ferromagnet/antiferromagnet metallic bilayers to laser excitation d...
The response of exchange coupled ferromagnet/antiferromagnet metallic bilayers to laser excitation d...
Spin currents can be generated on an ultrafast time scale by excitation of a ferromagnetic (FM) thin...
Spin currents can be generated on an ultrafast time scale by excitation of a ferromagnetic (FM) thin...
Spin currents can be generated on an ultrafast time scale by excitation of a ferromagnetic (FM) thin...
Spin currents can be generated on an ultrafast time scale by excitation of a ferromagnetic (FM) thin...
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...
We report on recent experiments addressing the interplay between magnetic ordering and spin/heat tra...