<p>Quantum entanglement is a fundamental resource for quantum information processing and serves as a critical benchmark for quantum hardware performance. Cluster states are a special class of entangled states that serve as universal resources for measurement-based quantum computation and possess an intrinsic symmetry-protected topological order, which confers robustness against symmetry-respecting noise. Here we report the scalable preparation and verification of genuine multipartite cluster states on the 105-qubit Zuchongzhi 3.1 superconducting processor. We achieve one-dimensional cluster states of up to 95 qubits and two-dimensional cluster states of up to 72 qubits. The symmetry-protected topological cluster states exhibit input-state-dependent robustness under symmetry-breaking perturbations due to an operational parity structure that enhances the performance of measurement-based quantum computation. Furthermore, we use our two-dimensional cluster states to implement the Deutsch–Jozsa algorithm within the measurement-based quantum computation framework, achieving higher output-state fidelity compared with traditional circuit-based models and a query efficiency advantage over classical approaches. Our work establishes a scalable platform that combines large-scale entanglement generation, symmetry-protected topological order and practical quantum algorithms to enable robust, fault-tolerant measurement-based quantum computation.</p>

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One- and two-dimensional cluster states for topological phase simulation and measurement-based quantum computation

  • Tao Jiang,
  • Jianbin Cai,
  • Junxiang Huang,
  • Naibin Zhou,
  • Yukun Zhang,
  • Jiahao Bei,
  • Guoqing Cai,
  • Sirui Cao,
  • Fusheng Chen,
  • Jiang Chen,
  • Kefu Chen,
  • Xiawei Chen,
  • Xiqing Chen,
  • Zhe Chen,
  • Zhiyuan Chen,
  • Zihua Chen,
  • Wenhao Chu,
  • Hui Deng,
  • Zhibin Deng,
  • Pei Ding,
  • Xun Ding,
  • Zhuzhengqi Ding,
  • Shuai Dong,
  • Bo Fan,
  • Daojin Fan,
  • Yuanhao Fu,
  • Dongxin Gao,
  • Lei Ge,
  • Jiacheng Gui,
  • Cheng Guo,
  • Shaojun Guo,
  • Xiaoyang Guo,
  • Lianchen Han,
  • Tan He,
  • Linyin Hong,
  • Yisen Hu,
  • He-Liang Huang,
  • Yong-Heng Huo,
  • Zuokai Jiang,
  • Honghong Jin,
  • Yunxiang Leng,
  • Dayu Li,
  • Dongdong Li,
  • Fangyu Li,
  • Jiaqi Li,
  • Jinjin Li,
  • Junyan Li,
  • Junyun Li,
  • Na Li,
  • Shaowei Li,
  • Wei Li,
  • Yuhuai Li,
  • Yuan Li,
  • Futian Liang,
  • Xuelian Liang,
  • Nanxing Liao,
  • Jin Lin,
  • Weiping Lin,
  • Dailin Liu,
  • Hongxiu Liu,
  • Maliang Liu,
  • Xinyu Liu,
  • Xuemeng Liu,
  • Yancheng Liu,
  • Haoxin Lou,
  • Yuwei Ma,
  • Lingxin Meng,
  • Hao Mou,
  • Kailiang Nan,
  • Binghan Nie,
  • Meijuan Nie,
  • Jie Ning,
  • Le Niu,
  • Wenyi Peng,
  • Haoran Qian,
  • Hao Rong,
  • Tao Rong,
  • Huiyan Shen,
  • Qiong Shen,
  • Hong Su,
  • Feifan Su,
  • Chenyin Sun,
  • Liangchao Sun,
  • Tianzuo Sun,
  • Yingxiu Sun,
  • Yimeng Tan,
  • Jun Tan,
  • Longyue Tang,
  • Wenbing Tu,
  • Jiafei Wang,
  • Biao Wang,
  • Chang Wang,
  • Chen Wang,
  • Chu Wang,
  • Jian Wang,
  • Liangyuan Wang,
  • Rui Wang,
  • Shengtao Wang,
  • Xiaomin Wang,
  • Xinzhe Wang,
  • Xunxun Wang,
  • Yeru Wang,
  • Zuolin Wei,
  • Jiazhou Wei,
  • Dachao Wu,
  • Gang Wu,
  • Jin Wu,
  • Yulin Wu,
  • Shiyong Xie,
  • Lianjie Xin,
  • Yu Xu,
  • Chun Xue,
  • Kai Yan,
  • Weifeng Yang,
  • Xinpeng Yang,
  • Yang Yang,
  • Yangsen Ye,
  • Zhenping Ye,
  • Chong Ying,
  • Jiale Yu,
  • Qinjing Yu,
  • Wenhu Yu,
  • Xiangdong Zeng,
  • Chen Zha,
  • Shaoyu Zhan,
  • Feifei Zhang,
  • Haibin Zhang,
  • Kaili Zhang,
  • Wen Zhang,
  • Yiming Zhang,
  • Yongzhuo Zhang,
  • Lixiang Zhang,
  • Guming Zhao,
  • Peng Zhao,
  • Xintao Zhao,
  • Youwei Zhao,
  • Zhong Zhao,
  • Luyuan Zheng,
  • Fei Zhou,
  • Liang Zhou,
  • Na Zhou,
  • Shifeng Zhou,
  • Shuang Zhou,
  • Zhengxiao Zhou,
  • Chengjun Zhu,
  • Qingling Zhu,
  • Guihong Zou,
  • Haonan Zou,
  • Qiang Zhang,
  • Chao-Yang Lu,
  • Cheng-Zhi Peng,
  • Xiao Yuan,
  • Ming Gong,
  • Xiaobo Zhu,
  • Jian-Wei Pan

摘要

Quantum entanglement is a fundamental resource for quantum information processing and serves as a critical benchmark for quantum hardware performance. Cluster states are a special class of entangled states that serve as universal resources for measurement-based quantum computation and possess an intrinsic symmetry-protected topological order, which confers robustness against symmetry-respecting noise. Here we report the scalable preparation and verification of genuine multipartite cluster states on the 105-qubit Zuchongzhi 3.1 superconducting processor. We achieve one-dimensional cluster states of up to 95 qubits and two-dimensional cluster states of up to 72 qubits. The symmetry-protected topological cluster states exhibit input-state-dependent robustness under symmetry-breaking perturbations due to an operational parity structure that enhances the performance of measurement-based quantum computation. Furthermore, we use our two-dimensional cluster states to implement the Deutsch–Jozsa algorithm within the measurement-based quantum computation framework, achieving higher output-state fidelity compared with traditional circuit-based models and a query efficiency advantage over classical approaches. Our work establishes a scalable platform that combines large-scale entanglement generation, symmetry-protected topological order and practical quantum algorithms to enable robust, fault-tolerant measurement-based quantum computation.