Three Transformer backflow fermionic wave functions for the finite-doping Hubbard model converge, after accuracy improvements, to the same state with coexisting superconducting and stripe orders, demonstrating that variational energy is insufficient to identify the ground state.
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The information lattice distinguishes metals from insulators via power-law versus exponential decay of information per scale in 1D tight-binding models.
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Beyond Variational Bias: Resolving Intertwined Orders in the Hubbard Model
Three Transformer backflow fermionic wave functions for the finite-doping Hubbard model converge, after accuracy improvements, to the same state with coexisting superconducting and stripe orders, demonstrating that variational energy is insufficient to identify the ground state.
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Information lattice approach to the metal-insulator transition
The information lattice distinguishes metals from insulators via power-law versus exponential decay of information per scale in 1D tight-binding models.