Your search keyword '"Vishal, Shokeen"' showing total 3 results

1. Element-Specific Magnetization Dynamics of Complex Magnetic Systems Probed by Ultrafast Magneto-Optical Spectroscopy

Author

Clemens von Korff Schmising, Felix Willems, Sangeeta Sharma, Kelvin Yao, Martin Borchert, Martin Hennecke, Daniel Schick, Ilie Radu, Christian Strüber, Dieter W. Engel, Vishal Shokeen, Jens Buck, Kai Bagschik, Jens Viefhaus, Gregor Hartmann, Bastian Manschwetus, Soeren Grunewald, Stefan Düsterer, Emmanuelle Jal, Boris Vodungbo, Jan Lüning, and Stefan Eisebitt

Subjects

ultrafast demagnetization dynamics, transient absorption spectroscopy, free electron laser, high harmonic generation, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The vision to manipulate and control magnetism with light is driven on the one hand by fundamental questions of direct and indirect photon-spin interactions, and on the other hand by the necessity to cope with ever growing data volumes, requiring radically new approaches on how to write, read and process information. Here, we present two complementary experimental geometries to access the element-specific magnetization dynamics of complex magnetic systems via ultrafast magneto-optical spectroscopy in the extreme ultraviolet spectral range. First, we employ linearly polarized radiation of a free electron laser facility to demonstrate decoupled dynamics of the two sublattices of an FeGd alloy, a prerequisite for all-optical magnetization switching. Second, we use circularly polarized radiation generated in a laboratory-based high harmonic generation setup to show optical inter-site spin transfer in a CoPt alloy, a mechanism which only very recently has been predicted to mediate ultrafast metamagnetic phase transitions.

Published

2020

2. Ultrafast manipulation of the NiO antiferromagnetic order

Author

Xiaocui, Wang, Robin Y, Engel, Igor, Vaskivskyi, Diego, Turenne, Vishal, Shokeen, Alexander, Yaroslavtsev, Oscar, Grånäs, Ronny, Knut, Jan O, Schunck, Siarhei, Dziarzhytski, Günter, Brenner, Ru-Pan, Wang, Marion, Kuhlmann, Frederik, Kuschewski, Wibke, Bronsch, Christian, Schüßler-Langeheine, Andriy, Styervoyedov, Stuart S P, Parkin, Fulvio, Parmigiani, Olle, Eriksson, Martin, Beye, and Hermann A, Dürr

Abstract

Wide-band-gap insulators such as NiO offer the exciting prospect of coherently manipulating electronic correlations with strong optical fields. Contrary to metals where rapid dephasing of optical excitation

Published

2022

3. Ultrafast manipulation of the NiO antiferromagnetic order via sub gap optical excitation

Author

Xiaocui Wang, Robin Y. Engel, Igor Vaskivskyi, Diego Turenne, Vishal Shokeen, Alexander Yaroslavtsev, Oscar Grånäs, Ronny Knut, Jan O. Schunck, Siarhei Dziarzhytski, Günter Brenner, Ru-Pan Wang, Marion Kuhlmann, Frederik Kuschewski, Wibke Bronsch, Christian Schüßler-Langeheine, Andriy Styervoyedov, Stuart S. P. Parkin, Fulvio Parmigiani, Olle Eriksson, Martin Beye, and Hermann A. Dürr

Subjects

Condensed Matter - Strongly Correlated Electrons, Strongly Correlated Electrons (cond-mat.str-el), Materials Quantum Complex and Functional Materials, ddc:540, FOS: Physical sciences, Condensed Matter::Strongly Correlated Electrons, Physical and Theoretical Chemistry, Condensed Matter Physics, Den kondenserade materiens fysik

Abstract

Faraday discussions 237, 300 - 316 (2022). doi:10.1039/d2fd00005a, Wide-band-gap insulators such as NiO offer the exciting prospect of coherently manipulating electronic correlations with strong optical fields. Contrary to metals where rapid dephasing of optical excitation via electronic processes occurs, the sub-gap excitation in charge-transfer insulators has been shown to couple to low-energy bosonic excitations. However, it is currently unknown if the bosonic dressing field is composed of phonons or magnons. Here we use the prototypical charge-transfer insulator NiO to demonstrate that 1.5 eV sub-gap optical excitation leads to a renormalised NiO band-gap in combination with a significant reduction of the antiferromagnetic order. We employ element-specific X-ray reflectivity at the FLASH free-electron laser to demonstrate the reduction of the upper band-edge at the O 1s–2p core–valence resonance (K-edge) whereas the antiferromagnetic order is probed via X-ray magnetic linear dichroism (XMLD) at the Ni 2p–3d resonance (L$_2$-edge). Comparing the transient XMLD spectral line shape to ground-state measurements allows us to extract a spin temperature rise of 65 ± 5 K for time delays longer than 400 fs while at earlier times a non-equilibrium spin state is formed. We identify transient mid-gap states being formed during the first 200 fs accompanied by a band-gap reduction lasting at least up to the maximum measured time delay of 2.4 ps. Electronic structure calculations indicate that magnon excitations significantly contribute to the reduction of the NiO band gap., Published by Soc., Cambridge [u.a.]

Published

2022