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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A symmetry-leveraging framework for fault-tolerant ancilla preparation in quantum BCH codes yields lower spatial overhead and logical error rates than standard distillation in simulations up to 127 qubits.
A Hyperbolic Cycle Basis algorithm is introduced within a unified framework for constructing and benchmarking CSS quantum error correction codes on hyperbolic lattices, with performance metrics evaluated on two example codes.
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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Efficient Fault-Tolerant Ancilla Preparation for Quantum BCH codes via Cyclic Symmetry
A symmetry-leveraging framework for fault-tolerant ancilla preparation in quantum BCH codes yields lower spatial overhead and logical error rates than standard distillation in simulations up to 127 qubits.
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Systematic Approach to Hyperbolic Quantum Error Correction Codes
A Hyperbolic Cycle Basis algorithm is introduced within a unified framework for constructing and benchmarking CSS quantum error correction codes on hyperbolic lattices, with performance metrics evaluated on two example codes.