Theoretical modeling of the formation of Skyrmions in Fe-Gd
POSTER
Abstract
Skyrmions are one of the most complex magnetic orders observed and consist of a localized excitation
constructed from a vortex-like, continuous rotation of magnetic spins, representing a topological quasi-
particle. Also, skyrmions are interesting candidates for future information technologies due to their
topological protection, mobility, size, and low energy consumption compared to domain walls or other
conventional technologies. Recently, using a soft X-ray pulse, we have shown the formation of the
skyrmions in the Fe-Gd lattice and provided insight into skyrmion-skyrmion interactions. Using Density
Functional Theory (DFT), we have focused on forming skyrmions in the Fe-Gd lattice. First, we studied
the seven-crystal symmetry of the FeGd system and found the magnetic ground state structure of the Fe-
Gd systems. Next, we calculated the contribution of DMI using DFT calculation and an accurate low-
energy model for spin-dynamic simulations. We found that the in-plane magnetic configuration shows a
significant amount of DM interaction, which could be a signature of Skyrmion formation.
constructed from a vortex-like, continuous rotation of magnetic spins, representing a topological quasi-
particle. Also, skyrmions are interesting candidates for future information technologies due to their
topological protection, mobility, size, and low energy consumption compared to domain walls or other
conventional technologies. Recently, using a soft X-ray pulse, we have shown the formation of the
skyrmions in the Fe-Gd lattice and provided insight into skyrmion-skyrmion interactions. Using Density
Functional Theory (DFT), we have focused on forming skyrmions in the Fe-Gd lattice. First, we studied
the seven-crystal symmetry of the FeGd system and found the magnetic ground state structure of the Fe-
Gd systems. Next, we calculated the contribution of DMI using DFT calculation and an accurate low-
energy model for spin-dynamic simulations. We found that the in-plane magnetic configuration shows a
significant amount of DM interaction, which could be a signature of Skyrmion formation.
Presenters
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Alana Okullo
Howard University
Authors
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Alana Okullo
Howard University
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Sougata Mardanya
Howard University, National Cheng Kung University
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Joshua J Turner
SLAC - Natl Accelerator Lab
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Arun Bansil
Northeastern University, Northeastern University, Boston, USA
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Sugata Chowdhury
Howard University