Hybrid entanglement and error correction in a scalable quantum network node
- URL: http://arxiv.org/abs/2408.07752v1
- Date: Wed, 14 Aug 2024 18:01:49 GMT
- Title: Hybrid entanglement and error correction in a scalable quantum network node
- Authors: Xiu-Ying Chang, Pan-Yu Hou, Wen-Gang Zhang, Xiang-Qian Meng, Ye-Fei Yu, Ya-Nan Lu, Yan-Qing Liu, Bin-Xiang Qi, Dong-Ling Deng, Lu-Ming Duan,
- Abstract summary: We report on precise and complex control in a hybrid quantum node based on a diamond color center.
We encode three memory qubits into a logical state using the three-qubit repetition code and entangle this logical qubit with a photonic qubit.
Our results demonstrate the feasibility of several key functionalities for next-generation quantum repeaters.
- Score: 6.267173249706118
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Recent breakthroughs have ushered the quantum network into a new era, where quantum information can be stored, transferred, and processed across multiple nodes on a metropolitan scale. A key challenge in this new era is enhancing the capabilities of individual nodes, providing precise and robust control over multiple qubits and advanced functionality for scalable quantum networks. Here, we report on precise and complex control in a hybrid quantum node based on a diamond color center. We demonstrate hybrid coherent control by entangling three types of qubits: an electron spin as an interface qubit, a nuclear spin with long memory time, and a flying photonic qubit, with their qubit frequencies spanning three distinct regimes from the optical domain to the rf domain. By incorporating two additional memory qubits, we encode three memory qubits into a logical state using the three-qubit repetition code and entangle this logical qubit with a photonic qubit. Leveraging hybrid qubits and precise control, we repeatedly read out the error syndromes of memory qubits through the electron spin, serving as an auxiliary qubit, then apply a real-time feedback operation to correct bit-flip errors. We execute and verify active error correction for up to twelve rounds and demonstrate the improvement over the uncorrected counterpart. Our results demonstrate the feasibility of several key functionalities for next-generation quantum repeaters, paving the way towards full-fledged metropolitan-scale quantum networks for a wide range of practical applications.
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