量子位元
Transmon公司
量子计算机
量子纠缠
量子
物理
光电子学
模块化设计
计算机科学
量子力学
操作系统
作者
Jingjing Niu,Libo Zhang,Yang Liu,Jiawei Qiu,Wenhui Huang,Jiaxing Huang,Hao Jia,Jiawei Liu,Ziyu Tao,Weiwei Wei,Yuxuan Zhou,Wanjing Zou,Yuanzhen Chen,Xiaowei Deng,Xiu–Hao Deng,Chang-Kang Hu,Ling Hu,Jian Li,Dian Tan,Yuan Xu
标识
DOI:10.1038/s41928-023-00925-z
摘要
Scaling is now a key challenge in superconducting quantum computing. One solution is to build modular systems in which smaller-scale quantum modules are individually constructed and calibrated, and then assembled into a larger architecture. This, however, requires the development of suitable interconnects. Here, we report low-loss interconnects based on pure aluminium coaxial cables and on-chip impedance transformers featuring quality factors up to $8.1 \times 10^5$, which is comparable to the performance of our transmon qubits fabricated on single-crystal sapphire substrate. We use these interconnects to link five quantum modules with inter-module quantum state transfer and Bell state fidelities up to 99\%. To benchmark the overall performance of the processor, we create maximally-entangled, multi-qubit Greenberger-Horne-Zeilinger (GHZ) states. The generated inter-module four-qubit GHZ state exhibits 92.0\% fidelity. We also entangle up to 12 qubits in a GHZ state with $55.8 \pm 1.8\%$ fidelity, which is above the genuine multipartite entanglement threshold of 1/2. These results represent a viable modular approach for large-scale superconducting quantum processors.
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