Fock space prethermalization and time-crystalline order on a quantum processor
Abstract
Periodically driven quantum many-body systems exhibit a wide variety of exotic nonequilibrium phenomena and provide a promising pathway for quantum applications. A fundamental challenge for stabilizing and harnessing these highly entangled states of matter is system heating by energy absorption from the drive. Here, we propose and demonstrate a disorder-free mechanism, dubbed Fock space prethermalization (FSP), to suppress heating. This mechanism divides the Fock-space network into linearly many sparse sub-networks, thereby prolonging the thermalization timescale even for initial states at high energy densities. Using 72 superconducting qubits, we observe an FSP-based time-crystalline order that persists over 120 cycles for generic initial Fock states. The underlying kinetic constraint of approximately conserved domain wall (DW) numbers is identified by measuring site-resolved correlators. Further, we perform finite-size scaling analysis for DW and Fock-space dynamics by varying system sizes, which reveals size-independent regimes for FSP-thermalization crossover and links the dynamical behaviors to the eigenstructure of the Floquet unitary. Our work establishes FSP as a robust mechanism for breaking ergodicity, and paves the way for exploring novel nonequilibrium quantum matter and its applications.
Keywords
Cite
@article{arxiv.2510.24059,
title = {Fock space prethermalization and time-crystalline order on a quantum processor},
author = {Zehang Bao and Zitian Zhu and Yang-Ren Liu and Zixuan Song and Feitong Jin and Xuhao Zhu and Yu Gao and Chuanyu Zhang and Ning Wang and Yiren Zou and Ziqi Tan and Aosai Zhang and Zhengyi Cui and Fanhao Shen and Jiarun Zhong and Yiyang He and Han Wang and Jia-Nan Yang and Yanzhe Wang and Jiayuan Shen and Gongyu Liu and Yihang Han and Yaozu Wu and Jinfeng Deng and Hang Dong and Pengfei Zhang and Hekang Li and Zhen Wang and Chao Song and Chen Cheng and Rubem Mondaini and Qiujiang Guo and Biao Huang and H. Wang},
journal= {arXiv preprint arXiv:2510.24059},
year = {2026}
}
Comments
8 pages, 4 figures + supplementary information