Dynamical decoupling extends QD electron spin coherence to 298 ns and improves simulated spin-photon-photon entanglement fidelity by 20% in a micropillar cavity.
Topological fault- tolerance in cluster state quantum computation
3 Pith papers cite this work. Polarity classification is still indexing.
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Large qLDPC blocks in distributed quantum computing enable Pauli-based computation to run up to 10x faster than surface codes for optimization algorithms by using spare nodes to bypass serialization bottlenecks.
Sparse qubit connectivity raises compiled depth in noisy IQP circuits, requiring lower effective noise to remain outside the classically simulatable regime compared to fully connected layouts.
citing papers explorer
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Dynamical decoupling of a quantum dot spin in a micropillar cavity for spin-multiphoton entanglement
Dynamical decoupling extends QD electron spin coherence to 298 ns and improves simulated spin-photon-photon entanglement fidelity by 20% in a micropillar cavity.
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Space-Time Tradeoffs of Pauli-Based Computation in Distributed qLDPC Architectures
Large qLDPC blocks in distributed quantum computing enable Pauli-based computation to run up to 10x faster than surface codes for optimization algorithms by using spare nodes to bypass serialization bottlenecks.
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The Impact of Qubit Connectivity on Quantum Advantage in Noisy IQP Circuits
Sparse qubit connectivity raises compiled depth in noisy IQP circuits, requiring lower effective noise to remain outside the classically simulatable regime compared to fully connected layouts.