Ultrafast spin transfer and its impact on the electronic structure.
Kamil BobowskiXinwei ZhengBjörn FrietschDominic LawrenzWibke BronschCornelius GahlBeatrice AndresChristian S StrüberRobert E CarleyMartin TeichmannAndreas ScherzSerguei MolodtsovCephise CachoRichard T ChapmanEmma SpringateMartin WeineltPublished in: Science advances (2024)
Optically induced intersite spin transfer (OISTR) promises manipulation of spin systems within the ultimate time limit of laser excitation. Following its prediction, signatures of ultrafast spin transfer between oppositely aligned spin sublattices have been observed in magnetic alloys and multilayers. However, it is known neither from theory nor from experiment whether the band structure immediately follows the ultrafast change in spin polarization or whether the exchange split bands remain rigid. We show that ultrafast spin transfer occurs even in ferromagnetic gadolinium metal. Charge transfer between localized surface and extended valence-band states leads to a decrease of the surface spin polarization. This synchronously alters the exchange splitting of the bulk valence bands during laser excitation. Moreover, the onset of demagnetization can be tuned by over 200 fs by changing the temperature-dependent spin mixing. Our results show a promising route to ultrafast control of the magnetization, widening the impact and applicability of OISTR.
Keyphrases
- room temperature
- density functional theory
- single molecule
- transition metal
- energy transfer
- electron transfer
- magnetic resonance imaging
- ionic liquid
- molecular dynamics
- gene expression
- dna methylation
- computed tomography
- magnetic resonance
- high speed
- endothelial cells
- contrast enhanced
- quantum dots
- diabetic rats
- solid phase extraction