Giant-atom quantum acoustodynamics in hybrid superconducting-phononic integrated circuits

Lintao Xiao; Bo Zhang; Yu Zeng; Xiaoxuan Pan; Jia-Qi Wang; Ziyue Hua; Hongwei Huang; Yifang Xu; Guangming Xue; Haifeng Yu; Xin-Biao Xu; Weiting Wang; Chang-Ling Zou; Luyan Sun

Giant-atom quantum acoustodynamics in hybrid superconducting-phononic integrated circuits

Lintao Xiao, Bo Zhang, Yu Zeng, Xiaoxuan Pan, Jia-Qi Wang, Ziyue Hua, Hongwei Huang, Yifang Xu, Guangming Xue, Haifeng Yu, Xin-Biao Xu, Weiting Wang, Chang-Ling Zou, Luyan Sun

Published December 18, 2025· quant-ph

Superconducting

Fabrication

Benchmarking

Abstract

We demonstrate a giant atom by coupling a superconducting transmon qubit to a lithium niobate phononic waveguide at two points separated by about 600 acoustic wavelengths, with a propagation delay of 125 ns. The giant atom yields non-Markovian relaxation dynamics characterized by phonon backflow and a frequency-dependent effective decay rate varying four-fold over merely 4 MHz, corresponding to a Purcell factor exceeding 40. Exploiting this frequency-dependent dissipation, we prepare quantum superposition states with high purity. Our results establish phononic integrated circuits as a versatile platform for giant-atom physics, providing highly tunable quantum devices for advanced quantum information processing.

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