Disorder-aware neural quantum states provide the first microscopic evidence for a pinned hole Wigner crystal near ν=2/3 that accounts for reentrant integer quantum Hall physics and reveals an electron-hole asymmetry in crystallization.
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Wigner crystal phase forms in monolayer WSe2 at low T and n and is observed optically via exciton diffraction enabled by large longitudinal-transverse splitting from intervalley exchange.
Rhombohedral graphene multilayers show an isospin cascade of electron crystal phases with non-zero Chern numbers and nearly degenerate topological states hosting extended quantum anomalous Hall effect as carrier density rises.
citing papers explorer
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Crystallization in the Fractional Quantum Hall Regime with Disorder-Aware Neural Quantum States
Disorder-aware neural quantum states provide the first microscopic evidence for a pinned hole Wigner crystal near ν=2/3 that accounts for reentrant integer quantum Hall physics and reveals an electron-hole asymmetry in crystallization.
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Optical probing of Wigner crystallization in monolayer WSe$_2$ via diffraction of longitudinal excitons
Wigner crystal phase forms in monolayer WSe2 at low T and n and is observed optically via exciton diffraction enabled by large longitudinal-transverse splitting from intervalley exchange.
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Various electronic crystal phases in rhombohedral graphene multilayers
Rhombohedral graphene multilayers show an isospin cascade of electron crystal phases with non-zero Chern numbers and nearly degenerate topological states hosting extended quantum anomalous Hall effect as carrier density rises.