DQMC simulations establish a direct SMG transition in a high-symmetry bilayer honeycomb lattice with fermion anomalous dimension η_ψ = 0.071(1), providing a quantitative constraint on candidate critical theories.
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DMRG and DQMC simulations confirm oxygen-centered charge stripes with reduced amplitude in the Emery model and show unidirectional stripe tendencies plus dominant B1g nematic susceptibility at accessible temperatures.
Particle doping of the triangular Hubbard model yields a Nagaoka supermetal whose anomalous transport and thermodynamic properties arise from a power-law divergent density of states at a higher-order Van Hove singularity.
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Symmetric Mass Generation in a Bilayer Honeycomb Lattice with $\mathrm{SU}(2)\times\mathrm{SU}(2)\times\mathrm{SU}(2)/\mathbb{Z}_2$ Symmetry
DQMC simulations establish a direct SMG transition in a high-symmetry bilayer honeycomb lattice with fermion anomalous dimension η_ψ = 0.071(1), providing a quantitative constraint on candidate critical theories.
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Robust fluctuating intertwined charge stripes in the Emery model
DMRG and DQMC simulations confirm oxygen-centered charge stripes with reduced amplitude in the Emery model and show unidirectional stripe tendencies plus dominant B1g nematic susceptibility at accessible temperatures.
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Nagaoka supermetal in the particle-doped triangular Hubbard model
Particle doping of the triangular Hubbard model yields a Nagaoka supermetal whose anomalous transport and thermodynamic properties arise from a power-law divergent density of states at a higher-order Van Hove singularity.