Insights on magnon topology and valley-polarization in 2D bilayer quantum magnets

AbstractMoiré superlattices created by the twisted stacking of two-dimensional crystals can host electronic bands with flat energy dispersion in which enhanced interactions promote correlated electron states. The twisted double bilayer graphene (TDBG), where two Bernal bilayer graphene are stacked with a twist angle, is such a moiré system with tunable flat bands. Here, we use gate-tuned scanning tunneling spectroscopy to directly demonstrate the tunability of the band structure of TDBG with an electric field and to show spectroscopic signatures of electronic correlations and topology for its flat band. Our spectroscopic experiments are in agreement with a continuum model of TDBG band structure and reveal signatures of a correlated insulator gap at partial filling of its isolated flat band. The topological properties of this flat band are probed with the application of a magnetic field, which leads to valley polarization and the splitting of Chern bands with a large effective g-factor.

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Asymptotic freedom in quantum magnets

Physical Review B ◽

10.1103/physrevb.92.220401 ◽

2015 ◽

Vol 92 (22) ◽

Cited By ~ 20

Author(s):

H. D. Scammell ◽

O. P. Sushkov

Keyword(s):

Asymptotic Freedom ◽

Quantum Magnets

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Probing resonating valence bond states in artificial quantum magnets

Nature Communications ◽

10.1038/s41467-021-21274-5 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Kai Yang ◽

Soo-Hyon Phark ◽

Yujeong Bae ◽

Taner Esat ◽

Philip Willke ◽

...

Keyword(s):

Quantum Information Processing ◽

Energy Levels ◽

Finite Size ◽

Valence Bond ◽

Exchange Interactions ◽

Atomic Scale ◽

Scanning Tunneling ◽

Many Body ◽

Quantum Magnets ◽

Resonating Valence Bond

AbstractDesigning and characterizing the many-body behaviors of quantum materials represents a prominent challenge for understanding strongly correlated physics and quantum information processing. We constructed artificial quantum magnets on a surface by using spin-1/2 atoms in a scanning tunneling microscope (STM). These coupled spins feature strong quantum fluctuations due to antiferromagnetic exchange interactions between neighboring atoms. To characterize the resulting collective magnetic states and their energy levels, we performed electron spin resonance on individual atoms within each quantum magnet. This gives atomic-scale access to properties of the exotic quantum many-body states, such as a finite-size realization of a resonating valence bond state. The tunable atomic-scale magnetic field from the STM tip allows us to further characterize and engineer the quantum states. These results open a new avenue to designing and exploring quantum magnets at the atomic scale for applications in spintronics and quantum simulations.

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