Van Hove Singularity-Driven Topological Magnetism in Twisted MoTe2
Heonjoon Park, Julian Stewart, Xiao-Wei Zhang, Taige Wang, Canxun Zhang + 13 more
TLDR
This paper reveals Van Hove singularity-driven topological magnetism in twisted MoTe2, leading to novel correlated phases and chiral spin textures.
Key contributions
- Discovered topological magnetism in twisted bilayer MoTe2, driven by Van Hove singularities and strong correlations.
- Observed a spontaneous anomalous Hall effect from a correlated intervalley-coherent antiferromagnetic state.
- Demonstrated a topological Hall effect from noncoplanar spin textures, transitioning to a C = -1 Chern insulator.
- Establishes tunable vHSs as a new route to chiral magnetism and engineering topological phase transitions.
Why it matters
This work opens new avenues for engineering quantum materials with tailored magnetic and topological properties. By leveraging tunable Van Hove singularities, it provides a pathway to design novel chiral magnetic states and topological phase transitions, crucial for future spintronic devices.
Original Abstract
Van Hove singularities (vHSs) strongly amplify electron interactions and can stabilize correlated phases in topological bands. Here we report signatures of topological magnetism in large-angle twisted bilayer MoTe2 driven by the interplay of vHSs, strong correlations, and valley topology. In a 4.8 degree device, electrostatic tuning to a vHS produces a spontaneous anomalous Hall hot spot near nu = -1. Combined transport and reflective magnetic circular dichroism measurements indicate that this regime is not governed by magnetization alone, but instead emerges from a correlated intervalley-coherent antiferromagnetic state that evolves with doping into a canted phase. With increasing magnetic field, the Hall response develops an additional finite-field component consistent with a topological Hall effect from a noncoplanar spin texture, before transitioning into a C = -1 Chern insulator. Our results establish tunable vHSs in moire topological bands as a route to chiral magnetism and engineering topological phase transitions.
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