Loss biasing turns Rydberg errors into erasures in neutral-atom QEC, restoring fault-tolerant Pauli error scaling and enabling optimal erasure scaling with loss-aware decoding for shorter cycles.
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Bichromatic tweezers with selected wavelengths and intensity ratio suppress differential AC Stark shifts in ⁸⁷Sr ³P₂, creating scalar and tensor magic conditions for qudit encoding.
Neutral-atom processor integrates atom motion with in-place entanglement to cut logical overhead, shown in Shor's variant, CX ladders, and [[16,4,4]] code experiments with 2-8x error improvements.
citing papers explorer
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Loss-biased fault-tolerant quantum error correction
Loss biasing turns Rydberg errors into erasures in neutral-atom QEC, restoring fault-tolerant Pauli error scaling and enabling optimal erasure scaling with loss-aware decoding for shorter cycles.
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Bichromatic Tweezers for Qudit Quantum Computing in ${}^{87}$Sr
Bichromatic tweezers with selected wavelengths and intensity ratio suppress differential AC Stark shifts in ⁸⁷Sr ³P₂, creating scalar and tensor magic conditions for qudit encoding.
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Demonstration of a Logical Architecture Uniting Motion and In-Place Entanglement
Neutral-atom processor integrates atom motion with in-place entanglement to cut logical overhead, shown in Shor's variant, CX ladders, and [[16,4,4]] code experiments with 2-8x error improvements.