Open-boundary transverse-field Ising model admits exact invertible duality, invertible critical symmetry, and spontaneous duality breaking from differing physical sensitivities to local perturbations.
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11 Pith papers cite this work. Polarity classification is still indexing.
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Numerical DMRG study of the anisotropic J1-J2 spin-1 chain uncovers two non-magnetic incommensurate floating Luttinger liquid phases emerging from the trimerized background, separated from the Haldane phase by a composite c=2 critical line.
A new non-engineered SU(4) fermion model exhibits high-temperature charge-4e superconductivity via unbiased quantum Monte Carlo, with Tc increasing linearly with coupling and a BKT transition marked by a charge-4e stiffness jump.
A U-Net-based ML pipeline reconstructs the complete phase field and quantized vortex charges in 2D Bose-Einstein condensates from density snapshots alone, using synthetic training data from projected Gross-Pitaevskii simulations.
Diabolical critical points are stable higher-codimension defects in parameter space of quantum and classical many-body systems, defined by non-trivial winding of nearby equilibrium states.
Flow alignment in nematic fluids creates bend-splay walls that lower defect nucleation thresholds and prevent recombination, replacing the reversible BKT transition with persistent unbound defects.
Nonreciprocal surface tension in the Nonreciprocal Cahn-Hilliard model induces defect motility and organization into target patterns and mosaic-waves whose large-scale dynamics belong to the anisotropic Kardar-Parisi-Zhang universality class.
Molecular dynamics simulations reveal that the CDW in monolayer TiSe2 melts via a two-step fluctuation regime with defects and domain walls, while anisotropic thermal fluctuations spontaneously stabilize an asymmetric 3Q chiral CDW with C2 symmetry.
Coupling to mesoscopic reservoirs generates temperature-increasing entropic barriers that suppress topological defect creation and transport, yielding three-regime correlation lengths in 1D Ising chains and double error reduction in finite-size 2D toric codes.
In the α-T3 lattice with on-site asymmetry, mean-field theory shows a superconducting gap that grows as a power law with interaction strength at flat-band filling, while the geometric part of the superfluid weight grows linearly and is enhanced by tuning α.
Frustrated quantum materials show topological spin-glass behavior with short-range correlations and low-energy excitations, unified by hydrodynamic spin modes and spin-jam states in a framework that bridges experiments and theory.
citing papers explorer
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Invertible Symmetry and Spontaneous Duality Breaking in the Transverse-Field Ising Model
Open-boundary transverse-field Ising model admits exact invertible duality, invertible critical symmetry, and spontaneous duality breaking from differing physical sensitivities to local perturbations.
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Non-magnetic floating phases in frustrated Haldane chains with a single-ion anisotropy
Numerical DMRG study of the anisotropic J1-J2 spin-1 chain uncovers two non-magnetic incommensurate floating Luttinger liquid phases emerging from the trimerized background, separated from the Haldane phase by a composite c=2 critical line.
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High-temperature charge-4e superconductivity in SU(4) interacting fermions
A new non-engineered SU(4) fermion model exhibits high-temperature charge-4e superconductivity via unbiased quantum Monte Carlo, with Tc increasing linearly with coupling and a BKT transition marked by a charge-4e stiffness jump.
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Machine Learning Phase Field Reconstruction in a Bose-Einstein Condensate
A U-Net-based ML pipeline reconstructs the complete phase field and quantized vortex charges in 2D Bose-Einstein condensates from density snapshots alone, using synthetic training data from projected Gross-Pitaevskii simulations.
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In search of diabolical critical points
Diabolical critical points are stable higher-codimension defects in parameter space of quantum and classical many-body systems, defined by non-trivial winding of nearby equilibrium states.
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Flow Coupling Alters Topological Phase Transition in Nematic Liquid Crystals
Flow alignment in nematic fluids creates bend-splay walls that lower defect nucleation thresholds and prevent recombination, replacing the reversible BKT transition with persistent unbound defects.
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Nonreciprocal surface tension: anisotropy-induced defect motility and organization
Nonreciprocal surface tension in the Nonreciprocal Cahn-Hilliard model induces defect motility and organization into target patterns and mosaic-waves whose large-scale dynamics belong to the anisotropic Kardar-Parisi-Zhang universality class.
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Fluctuation-driven multi-step charge density wave transition in monolayer TiSe$_2$
Molecular dynamics simulations reveal that the CDW in monolayer TiSe2 melts via a two-step fluctuation regime with defects and domain walls, while anisotropic thermal fluctuations spontaneously stabilize an asymmetric 3Q chiral CDW with C2 symmetry.
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Entropic Barriers and the Kinetic Suppression of Topological Defects
Coupling to mesoscopic reservoirs generates temperature-increasing entropic barriers that suppress topological defect creation and transport, yielding three-regime correlation lengths in 1D Ising chains and double error reduction in finite-size 2D toric codes.
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Superconductivity and geometric superfluid weight of a tunable flat band system
In the α-T3 lattice with on-site asymmetry, mean-field theory shows a superconducting gap that grows as a power law with interaction strength at flat-band filling, while the geometric part of the superfluid weight grows linearly and is enhanced by tuning α.
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Topological spin freezing in frustrated quantum materials
Frustrated quantum materials show topological spin-glass behavior with short-range correlations and low-energy excitations, unified by hydrodynamic spin modes and spin-jam states in a framework that bridges experiments and theory.