Interaction-induced topological pumping in a solid-state quantum system
Abstract
As the basis for generating multi-particle quantum correlations, inter-particle interaction plays a crucial role in collective quantum phenomena, quantum phase transitions, and quantum information processing. It can profoundly alter the band structure of quantum many-body systems and give rise to exotic topological phenomena. Conventional topological pumping, which has been well demonstrated in driven linear or noninteracting systems, may break down in the presence of strong interaction. However, the interplay between band topology and interaction could also induce emergent topological pumping of interacting particles, but its experimental realization has proven challenging. Here we demonstrate interaction-induced topological pumping in a solid-state quantum system comprising an array of 36 superconducting qubits. With strong interaction inherent in the qubits and site-resolved controllability of the lattice potential and hopping strength, we realize the topological Thouless pumping of single and two bounded particles. Beyond these topological phenomena with linear or noninteracting counterparts, we also observe topologically resonant tunneling and asymmetric edge-state transport of interacting particles. Our work creates a paradigm for multi-particle topological effects, and provides a new pathway to the study of exotic topological phenomena, many-body quantum transport, and quantum information transfer.
Cite
@article{arxiv.2303.04582,
title = {Interaction-induced topological pumping in a solid-state quantum system},
author = {Ziyu Tao and Wenhui Huang and Jingjing Niu and Libo Zhang and Yongguan Ke and Xiu Gu and Ling Lin and Jiawei Qiu and Xuandong Sun and Xiaohan Yang and Jiajian Zhang and Jiawei Zhang and Shuxiang Zhao and Yuxuan Zhou and Xiaowei Deng and Changkang Hu and Ling Hu and Jian Li and Yang Liu and Dian Tan and Yuan Xu and Tongxing Yan and Yuanzhen Chen and Chaohong Lee and Youpeng Zhong and Song Liu and Dapeng Yu},
journal= {arXiv preprint arXiv:2303.04582},
year = {2025}
}
Comments
8+29 pages, 4+24 figures