Floquet engineering of nonreciprocal light-induced dipolar interactions in tweezer arrays realizes beamsplitter, squeezing operations, negative-mass-like signatures, and tunable complex eigenfrequencies.
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8 Pith papers cite this work. Polarity classification is still indexing.
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Levitated nanomechanical oscillator senses 10 zeptonewton forces below quantum zero-point fluctuation by preparing a squeezed state through potential modulation and detecting force via time-of-flight displacement.
The layer-antisymmetric pair-phase resonance sits at the bonding-antibonding splitting 2t_h because the antisymmetric bubble reduces pointwise to the static symmetric bubble at that frequency.
A model-agnostic randomized dissipative cooling protocol drives generic strongly correlated fermionic systems to their low-energy manifold using local ancilla couplings with random energy splittings.
Dark states unaffected by decentered interactions create exactly solvable subspaces in a nonintegrable 1D box-trap model for bosons and fermions.
A quasi-2D quantum degenerate Bose mixture of 23Na and 87Rb atoms was prepared and shown to exhibit quantum immiscibility in equilibrium density profiles consistent with mean-field theory.
A resonant-manifold framework unifies manifold and branch DQPTs by linking them to resonances within the initial manifold or a transitional manifold, with regularity tied to manifold multiplicity, shown in Z2 LGT quenches.
A VQE quantum-computing method for nuclear lattice models shows ground-state energies for 2H, 3H, and 4He approaching experimental values with increasing lattice size.
citing papers explorer
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Floquet engineering of nonreciprocal light-induced dipolar interactions
Floquet engineering of nonreciprocal light-induced dipolar interactions in tweezer arrays realizes beamsplitter, squeezing operations, negative-mass-like signatures, and tunable complex eigenfrequencies.
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Time-of-flight force sensing below the quantum zero-point fluctuation
Levitated nanomechanical oscillator senses 10 zeptonewton forces below quantum zero-point fluctuation by preparing a squeezed state through potential modulation and detecting force via time-of-flight displacement.
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Layer-antisymmetric pair-phase resonance at the bonding-antibonding splitting in the AA-stacked bilayer attractive Hubbard model
The layer-antisymmetric pair-phase resonance sits at the bonding-antibonding splitting 2t_h because the antisymmetric bubble reduces pointwise to the static symmetric bubble at that frequency.
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Model-agnostic cooling algorithms for strongly interacting fermions
A model-agnostic randomized dissipative cooling protocol drives generic strongly correlated fermionic systems to their low-energy manifold using local ancilla couplings with random energy splittings.
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Partial solvability induced by dark states in a box trap with decentered two-body interaction
Dark states unaffected by decentered interactions create exactly solvable subspaces in a nonintegrable 1D box-trap model for bosons and fermions.
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Preparation of quasi-two-dimensional Bose mixture of ultracold $^{23}$Na and $^{87}$Rb atoms
A quasi-2D quantum degenerate Bose mixture of 23Na and 87Rb atoms was prepared and shown to exhibit quantum immiscibility in equilibrium density profiles consistent with mean-field theory.
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Unified resonant-manifold framework for dynamical quantum phase transitions
A resonant-manifold framework unifies manifold and branch DQPTs by linking them to resonances within the initial manifold or a transitional manifold, with regularity tied to manifold multiplicity, shown in Z2 LGT quenches.
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Quantum computing for effective nuclear lattice model
A VQE quantum-computing method for nuclear lattice models shows ground-state energies for 2H, 3H, and 4He approaching experimental values with increasing lattice size.