Ghost-GA provides an efficient way to compute the magnetic phase diagram of the anisotropic triangular Hubbard model, matching DMFT closely and ruling out the 1D AF phase.
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4 Pith papers cite this work. Polarity classification is still indexing.
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UNVERDICTED 4representative citing papers
A generalized continuum model for twisted kagome bilayers predicts higher-order magic angles causing flat bands and non-trivial topology induced solely by twisting.
ARPES on tMoTe2 reveals non-monotonic hole effective mass versus twist angle peaking near 2 degrees, consistent with predicted magic-angle band flattening, plus doping-dependent band evolution confirming a direct gap.
Pressure tunes band flatness and geometry in tMoTe2 to control FCI and GWC phases and their topological transitions at fractional fillings.
citing papers explorer
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Magnetic phases of the anisotropic triangular Hubbard model from the ghost-Gutzwiller approximation in the rotating spin-frame
Ghost-GA provides an efficient way to compute the magnetic phase diagram of the anisotropic triangular Hubbard model, matching DMFT closely and ruling out the 1D AF phase.
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Twisted Kagome Bilayers: Higher-Order Magic Angles, Topological Flat Bands, and Sublattice Interference
A generalized continuum model for twisted kagome bilayers predicts higher-order magic angles causing flat bands and non-trivial topology induced solely by twisting.
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Non-monotonic band flattening near the magic angle of twisted bilayer MoTe$_2$
ARPES on tMoTe2 reveals non-monotonic hole effective mass versus twist angle peaking near 2 degrees, consistent with predicted magic-angle band flattening, plus doping-dependent band evolution confirming a direct gap.
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Pressure-Tunable Generalized Wigner Crystal and Fractional Chern Insulator in twisted MoTe$_2$
Pressure tunes band flatness and geometry in tMoTe2 to control FCI and GWC phases and their topological transitions at fractional fillings.