A graph neural network path planner and phase-aware Gerchberg-Saxton algorithm enable defect-free assembly of 10,000-atom arrays in under 6 ms, faster than typical atom loss times.
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9 Pith papers cite this work. Polarity classification is still indexing.
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Long-range interactions in quantum spin chains enable the Efimov effect for magnons by inducing continuous scale invariance in two-body states that becomes discrete in the three-body problem.
EIT cooling with fluorescence imaging achieves 99.7% readout fidelity and 98.2% survival for 87Rb atom arrays in 2.3 G fields, validated up to 10 G.
Experiments, numerics, and analytics on Rydberg atoms in a Lieb lattice reveal density-wave phases including a fluctuation-stabilized collinear order, a quantum liquid-vapor transition with hysteresis, and kinetically constrained slow relaxation after quenches.
SNT merges SV and PEC for subspace-tailored error mitigation in Trotterized FHM simulations, mapping out optimal combinations by hardware quality and shot budget while quantifying when noisy devices could surpass classical methods.
Optimized double-pulse laser shapes from D-MORPH quantum optimal control achieve ~99% Bell-state fidelity in Rydberg atoms and remain robust to moderate amplitude noise while phase noise remains the dominant limiter.
A tunable chain of Rydberg atoms in tweezers mediates both coherent and dissipative entanglement between two distant micro-electromechanical oscillators.
Optimizing collision gates for ultracold fermions in double-well potentials reveals momentum-dependent interaction energies that are higher for atoms starting in separate subwells than the same subwell, supporting case-specific high-fidelity gates beyond Fermi-Hubbard models.
citing papers explorer
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An Algorithm for Fast Assembling Large-Scale Defect-Free Atom Arrays
A graph neural network path planner and phase-aware Gerchberg-Saxton algorithm enable defect-free assembly of 10,000-atom arrays in under 6 ms, faster than typical atom loss times.
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Efimov Effect in Long-range Quantum Spin Chains
Long-range interactions in quantum spin chains enable the Efimov effect for magnons by inducing continuous scale invariance in two-body states that becomes discrete in the three-body problem.
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Loading and Imaging Atom Arrays via Electromagnetically Induced Transparency
EIT cooling with fluorescence imaging achieves 99.7% readout fidelity and 98.2% survival for 87Rb atom arrays in 2.3 G fields, validated up to 10 G.
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Quantum criticality and nonequilibrium dynamics on a Lieb lattice of Rydberg atoms
Experiments, numerics, and analytics on Rydberg atoms in a Lieb lattice reveal density-wave phases including a fluctuation-stabilized collinear order, a quantum liquid-vapor transition with hysteresis, and kinetically constrained slow relaxation after quenches.
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Near-Term Fermionic Simulation with Subspace Noise Tailored Quantum Error Mitigation
SNT merges SV and PEC for subspace-tailored error mitigation in Trotterized FHM simulations, mapping out optimal combinations by hardware quality and shot budget while quantifying when noisy devices could surpass classical methods.
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Noise-Robust Ultrafast Entanglement Generation in Rydberg Atoms via Quantum Optimal Control
Optimized double-pulse laser shapes from D-MORPH quantum optimal control achieve ~99% Bell-state fidelity in Rydberg atoms and remain robust to moderate amplitude noise while phase noise remains the dominant limiter.
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Entanglement of mechanical oscillators mediated by a Rydberg tweezer chain
A tunable chain of Rydberg atoms in tweezers mediates both coherent and dissipative entanglement between two distant micro-electromechanical oscillators.
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Optimizing two-qubit gates for ultracold fermions in optical lattices
Optimizing collision gates for ultracold fermions in double-well potentials reveals momentum-dependent interaction energies that are higher for atoms starting in separate subwells than the same subwell, supporting case-specific high-fidelity gates beyond Fermi-Hubbard models.
- Entangling gate performance and fidelity limits with neutral atom F\"orster resonances