Koh Jin Ming, Tai Tommy, Lee Ching Hua
Division of Physics, Mathematics and Astronomy, Caltech, Pasadena, CA, 91125, USA.
A*STAR Quantum Innovation Centre (Q.InC), Institute of High Performance Computing (IHPC), Agency for Science, Technology and Research (A*STAR), 1 Fusionopolis Way, #16-16 Connexis, Singapore, 138632, Republic of Singapore.
Nat Commun. 2024 Jul 10;15(1):5807. doi: 10.1038/s41467-024-49648-5.
Programmable quantum simulators may one day outperform classical computers at certain tasks. But at present, the range of viable applications with noisy intermediate-scale quantum (NISQ) devices remains limited by gate errors and the number of high-quality qubits. Here, we develop an approach that places digital NISQ hardware as a versatile platform for simulating multi-dimensional condensed matter systems. Our method encodes a high-dimensional lattice in terms of many-body interactions on a reduced-dimension model, thereby taking full advantage of the exponentially large Hilbert space of the host quantum system. With circuit optimization and error mitigation techniques, we measured on IBM superconducting quantum processors the topological state dynamics and protected mid-gap spectra of higher-order topological lattices, in up to four dimensions, with high accuracy. Our projected resource requirements scale favorably with system size and lattice dimensionality compared to classical computation, suggesting a possible route to useful quantum advantage in the longer term.
可编程量子模拟器也许有朝一日在某些任务上能超越经典计算机。但目前,有噪声的中等规模量子(NISQ)设备的可行应用范围仍受门错误和高质量量子比特数量的限制。在此,我们开发了一种方法,将数字NISQ硬件作为模拟多维凝聚态系统的通用平台。我们的方法通过在低维模型上的多体相互作用对高维晶格进行编码,从而充分利用主体量子系统指数级大的希尔伯特空间。通过电路优化和误差缓解技术,我们在IBM超导量子处理器上高精度地测量了高达四维的高阶拓扑晶格的拓扑态动力学和受保护的能隙中光谱。与经典计算相比,我们预计的资源需求随系统大小和晶格维度的增长较为有利,这表明从长远来看可能存在实现有用量子优势的途径。
