Assessing Teleportation of Logical Qubits in a Distributed Quantum Architecture under Error Correction
Abstract: Quantum computing is facing challenges in terms of scaling to thousands of qubits and implementing quantum error correction (QEC). Scaling efforts focus on connecting multiple smaller quantum devices in a distributed manner while error correction, as a means to overcome noisy physical qubits, is being addressed by developing denser codes with protocols for logical qubits and logical quantum gates. Teleportation of quantum states becomes an important operation as it transfers states from one node to another node within a distributed device. For physical qubits, today's high quantum network noise rates prevent the teleportation of states with useful accuracy. By employing QEC, we show that logical qubits can be teleported between nodes under Surface Code and qLDPC encodings with very low logical error rates, even with network noise in near-term regimes. We use circuit-level simulations to assess physical and network noise regimes ranging from $10{-1}$ to $10{-6}$. This is a wider range than typically studied in circuit level simulations and understanding the behavior of QEC codes in these regimes is necessary for achieving accurate computation.
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