“Quantum Geometric Nesting” and Solvable Model Flat-Band Systems

Han, Zhaoyu; Herzog-Arbeitman, Jonah; Bernevig, B. Andrei; Kivelson, Steven A.

doi:10.1103/physrevx.14.041004

Phys. Rev. X

2024

DOI: 10.1103/physrevx.14.041004

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“Quantum Geometric Nesting” and Solvable Model Flat-Band Systems

Zhaoyu Han,

Jonah Herzog-Arbeitman,

B. Andrei Bernevig

et al.

Abstract: We introduce the concept of “quantum geometric nesting” (QGN) to characterize the idealized ordering tendencies of certain flat-band systems implicit in the geometric structure of the flat-band subspace. Perfect QGN implies the existence of an infinite class of local interactions that can be explicitly constructed and give rise to solvable ground states with various forms of possible fermion bilinear order, including flavor ferromagnetism, density waves, and superconductivity. For the ideal Hamiltonians constr… Show more

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Cited by 3 publications

References 115 publications

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Pair size and quantum geometry in a multiband Hubbard model

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2025

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Pair size and quantum geometry in a multiband Hubbard model

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Enhanced Pair-Density-Wave Vertices in a Bilayer Hubbard Model at Half Filling

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Huang

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Ideal Chern bands with strong short-range repulsion: Applications to correlated metals, superconductivity, and topological order

Wilhelm,

Läuchli,

Scheurer

2024

Phys. Rev. Research

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Motivated by recent experiments on correlated van der Waals materials, including twisted and rhombohedral graphene and twisted WSe2, we perform an analytical and numerical study of the effects of strong on-site and short-range interactions in fractionally filled ideal Chern bands. We uncover an extensive nontrivial ground state manifold within the band filling range 0<ν<1 and introduce a general principle, the “three-rule,” for combining flat band wave functions, which governs their zero-energy property on the torus geometry. Based on the structure of these wave functions, we develop a variational approach that reveals distinct phases under different perturbations: metallic behavior emerges from a finite dispersion, and superconductivity is induced by attractive Cooper channel interactions. Our approach, not reliant on the commonly applied mean-field approximations, provides an analytical expression for the macroscopic wave function of the off-diagonal long-range order correlator, attributing pairing susceptibility to the set of nontrivial zero-energy ground state wave functions. Extending to finite screening lengths and beyond the ideal limit using exact diagonalization simulations, we demonstrate the peculiar structure in the many-body wave function's coefficients to be imprinted in the low-energy spectrum of the topologically ordered Halperin spin-singlet state. Our findings also make connections to frustration-free models of noncommuting projector Hamiltonians, potentially aiding the future construction of exact ground states for various fractional fillings. Published by the American Physical Society 2024

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“Quantum Geometric Nesting” and Solvable Model Flat-Band Systems

Cited by 3 publications

References 115 publications

Pair size and quantum geometry in a multiband Hubbard model

Pair size and quantum geometry in a multiband Hubbard model

Enhanced Pair-Density-Wave Vertices in a Bilayer Hubbard Model at Half Filling

Ideal Chern bands with strong short-range repulsion: Applications to correlated metals, superconductivity, and topological order

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