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Programmable higher-order nonequilibrium topological phases on a superconducting quantum processor

Haoran Qian, Ming Gong, Jia-Hui Zhang, Shaojun Guo, Chen Zha, Fusheng Chen, Yangsen Ye, Yulin Wu, Sirui Cao, Chong Ying, Qingling Zhu, He-Liang Huang, Youwei Zhao, Shaowei Li, Jiale Yu, Daojin Fan, Dachao Wu, Hong Su, Hui Deng, Hao Rong, Yuan Li, Kaili Zhang, Tung-Hsun Chung, Futian Liang, Jing Lin, Yu Xu, Cheng Guo, Na Li, Kai Yan, Feifan Su, Gang Wu, Yong-Heng Huo, Cheng-Zhi Peng, Chao‐Yang Lu, Feng Mei, Suotang Jia, Xiaobo Zhu, Jian-Wei Pan

2025Science7 citationsDOI

Abstract

Topological phases of matter are of both fundamental and practical interest. In this study, we implemented both equilibrium and nonequilibrium higher-order topological phases using a two-dimensional programmable superconducting quantum processor. Quantum programming of nonequilibrium higher-order topological phases was achieved by constructing quantum circuits comprising >50 cycles of Floquet operators on a six-by-six qubit array. Additionally, we introduce a universal approach based on measuring the dynamics of chiral density to identify distinct nonequilibrium higher-order topological features, including Floquet corner topological invariants and π-energy topological corner modes. Our work may enable the use of programmable quantum processors to explore exotic higher-order nonequilibrium topological phases of matter.

Topics & Concepts

Non-equilibrium thermodynamicsFloquet theoryPhysicsTopology (electrical circuits)QuantumTopological entropy in physicsTopological orderQubitTopological degeneracyQuantum computerQuantum mechanicsSuperconductivityWork (physics)Topological quantum computerSymmetry protected topological orderQuantum simulatorTopological quantum numberQuantum circuitTheoretical physicsQuantum Computing Algorithms and ArchitectureTopological Materials and PhenomenaQuantum many-body systems
Programmable higher-order nonequilibrium topological phases on a superconducting quantum processor | Litcius