Litcius/Paper detail

Topological prethermal strong zero modes on superconducting processors

Feitong Jin, Si Jiang, Xuhao Zhu, Zehang Bao, Fanhao Shen, Ke Wang, Zitian Zhu, Shibo Xu, Zixuan Song, Jiachen Chen, Ziqi Tan, Yaozu Wu, Chuanyu Zhang, Yu Gao, Ning Wang, Yiren Zou, Aosai Zhang, Tingting Li, Jiarun Zhong, Zhengyi Cui, Yihang Han, Yiyang He, Han Wang, Jianan Yang, Yanzhe Wang, Jiayuan Shen, Gongyu Liu, Jinfeng Deng, Hang Dong, Pengfei Zhang, Weikang Li, Dong Yuan, Zhide Lu, Zheng-Zhi Sun, Hekang Li, Junxiang Zhang, Chao Song, Zhen Wang, Qiujiang Guo, Francisco Machado, Jack Kemp, Thomas Iadecola, Norman Y. Yao, Hui Wang, Dong-Ling Deng

2025Nature15 citationsDOIOpen Access PDF

Abstract

Abstract Symmetry-protected topological phases 1–4 cannot be described by any local order parameter and are beyond the conventional symmetry-breaking model 5 . They are characterized by topological boundary modes that remain stable under symmetry respecting perturbations 1–4,6–8 . In clean, gapped systems without disorder, the stability of these edge modes is restricted to the zero-temperature manifold; at finite temperatures, interactions with mobile thermal excitations lead to their decay 9–11 . Here we report the observation of a distinct type of topological edge mode 12–14 , which is protected by emergent symmetries and persists across the entire spectrum, in an array of 100 programmable superconducting qubits. Through digital quantum simulation of a one-dimensional disorder-free stabilizer Hamiltonian, we observe robust long-lived topological edge modes over up to 30 cycles for a wide range of initial states. We show that the interaction between these edge modes and bulk excitations can be suppressed by dimerizing the stabilizer strength, leading to an emergent U(1) × U(1) symmetry in the prethermal regime of the system. Furthermore, we exploit these topological edge modes as logical qubits and prepare a logical Bell state, which exhibits persistent coherence, despite the system being disorder-free and at finite temperature. Our results establish a viable digital simulation approach 15–18 to experimentally study topological matter at finite temperature and demonstrate a potential route to construct long-lived, robust boundary qubits in disorder-free systems.

Topics & Concepts

SuperconductivityZero (linguistics)Topology (electrical circuits)PhysicsCondensed matter physicsMathematicsCombinatoricsLinguisticsPhilosophyQuantum many-body systemsTopological Materials and PhenomenaModel Reduction and Neural Networks