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Quantum Simulation
Super-Moiré Spin Textures in Twisted Antiferromagnets
arXiv
Authors: King Cho Wong, Ruoming Peng, Eric Anderson, Jackson Ross, Bowen Yang, Meixin Cheng, Sreehari Jayaram, Malik Lenger, Xuankai Zhou, Yan Tung Kong, Takashi Taniguchi, Kenji Watanabe, Michael A. McGuire, Rainer Stöhr, Adam Wei Tsen, Elton J. G. Santos, Xiaodong Xu, Jörg Wrachtrup
Year
2025
Paper ID
17919
Status
Preprint
Abstract Read
~2 min
Abstract Words
189
Citations
N/A
Abstract
Stacking two-dimensional (2D) layered materials offers a powerful platform to engineer electronic and magnetic states. In general, the resulting states, such as Moiré magnetism, have a periodicity at the length scale of the Moiré unit cell. Here, we report a new type of magnetism - dubbed a super-Moiré magnetic state - which is characterized by long-range magnetic textures extending beyond the single Moiré unit cell - in twisted double bilayer chromium triiodide tDB CrI$3$. We found that at small twist angles, the size of the spontaneous magnetic texture increases with twist angle, opposite to the underlying Moiré periodicity. The spin-texture size reaches a maximum of about 300 nm in 1.1° twisted devices, an order of magnitude larger than the underlying Moiré wavelength, and vanishes at twist angles above 2°. Employing scanning quantum spin magnetometry, the obtained vector field maps suggest the formation of antiferromagnetic Néel-type skyrmions spanning multiple Moiré cells. The twist-angle-dependent study combined with large-scale atomistic simulations suggests that complex magnetic competition between the Dzyaloshinskii--Moriya interaction, magnetic anisotropy, and exchange interactions controlled by the relative rotation of the layers produces the topological textures which arise in the super-Moiré spin orders.
Why This Paper Matters
- This paper contributes to the Quantum Simulation research area in the Quantum Articles archive.
- It adds a 2025 reference point for readers tracking recent quantum research.
- Stacking two-dimensional (2D) layered materials offers a powerful platform to engineer electronic and magnetic states.
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