中科大×山西大学合作发表最新Science论文

Core Insights - The article discusses a significant breakthrough in the field of quantum simulation, specifically the realization and detection of higher-order nonequilibrium topological phases (HOTPs) using a programmable superconducting quantum processor [1][5]. Group 1: Research Background - Topological phases have emerged as a crucial research direction in condensed matter physics and quantum simulation, with higher-order topological phases challenging traditional bulk-boundary correspondence [3]. - The realization of higher-order topological phases in quantum systems has been a scientific challenge, with potential implications for revealing the quantum nature of topological states and enabling topological quantum computing based on non-Abelian statistics [4]. Group 2: Experimental Achievements - The research team successfully implemented quantum simulation and detection of both balanced and nonequilibrium second-order topological phases using the "Zuchongzhi 2" superconducting quantum processor [5]. - They developed theoretical designs for static and Floquet quantum circuits to construct higher-order topological Hamiltonians in a two-dimensional superconducting qubit array, addressing key challenges in the field [5]. - The experimental setup involved a 6×6 qubit array, where the team executed up to 50 Floquet periods of evolution operations, successfully realizing four different types of nonequilibrium second-order topological phases and exploring their energy spectra, dynamical behaviors, and topological invariants [5][7].