A two-dimensional dissipative quantum cellular automaton achieves passive quantum error correction with a nonzero noise threshold and supports fault-tolerant universal computation.
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3 Pith papers cite this work. Polarity classification is still indexing.
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quant-ph 3years
2026 3verdicts
UNVERDICTED 3representative citing papers
An FPGA-based neural-network decoder achieves 550 ns deterministic closed-loop latency for real-time distance-3 surface code error correction on a superconducting processor, matching offline decoding performance.
In-patch multiplexing reduces expected attempts per accepted logical magic state by 45-79% at physical error rate 2e-3 for distances 3 and 5 while leaving the escape stage unchanged.
citing papers explorer
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Quantum Memory and Autonomous Computation in Two Dimensions
A two-dimensional dissipative quantum cellular automaton achieves passive quantum error correction with a nonzero noise threshold and supports fault-tolerant universal computation.
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Real-time Surface-Code Error Correction Using an FPGA-based Neural-Network Decoder
An FPGA-based neural-network decoder achieves 550 ns deterministic closed-loop latency for real-time distance-3 surface code error correction on a superconducting processor, matching offline decoding performance.
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Reducing Postselection Overhead in Magic-State Cultivation by In-Patch Multiplexing
In-patch multiplexing reduces expected attempts per accepted logical magic state by 45-79% at physical error rate 2e-3 for distances 3 and 5 while leaving the escape stage unchanged.