量子互联是构建未来量子互联网、实现分布式量子计算与量子增强传感的核心技术。构建可扩展的量子网络，亟需发展能够连接诸如超导、原子、固态色心等不同量子平台的核心器件，包括连接微波与光学光子的量子频率转换器、延长量子态寿命的量子存储器以及实现超越标准量子极限的量子传感器。本研究组围绕这一需求，以片上集成光-力-磁混合系统为核心技术路径，针对以上核心功能模块开展系统性研究，旨在为未来大规模量子网络提供关键的基础器件与技术解决方案。我们的研究涵盖微纳加工、低温测量、微波光子学、量子光学等多学科交叉，欢迎对微纳光学、量子物理与前沿技术感兴趣的同学加入我们。

Research Papers

1.       G.-T. Xu#, Z. Shen#, M. Zhang#, Y. Wang, S. Wan, Y. Yang, T. Zhang, L. Bi, F.-W. Sun, G.-C. Guo and C.-H. Dong*, “Kerr-induced synchronization of a broadband magnon-phonon hybrid frequency comb,” Phys. Rev. Lett. 135, 203604 (2025).

2.       Y. Wang#, M. Zhang#, Z. Shen*, G.-T. Xu, R. Niu, F.-W. Sun, G.-C. Guo, and C.-H. Dong*, “Optomechanical frequency comb based on multiple nonlinear dynamics,” Phys. Rev. Lett. 132, 163603 (2024).

3.       Z. Shen#, Y.-L. Zhang#, Y. Chen, Y.-F. Xiao, C.-L. Zou, G.-C. Guo, and C.-H. Dong*, “Nonreciprocal frequency conversion and mode routing in a microresonator,” Phys. Rev. Lett. 130, 013601 (2023).

4.       G.-T. Xu#, M. Zhang#, Y. Wang, Z. Shen*, G.-C. Guo, C.-H. Dong*, “Magnonic frequency comb in the magnomechanical resonator,” Phys. Rev. Lett. 131, 243601 (2023).

5.       Z. Shen#, G.-T. Xu#, M. Zhang#, Y.-L. Zhang, Y. Wang, C.-Z. Chai, C.-L. Zou, G.-C. Guo, and C.-H. Dong*, “Coherent coupling between phonons, magnons and photons,” Phys. Rev. Lett. 129, 243601 (2022).

6.       Z. Shen, Y.-L. Zhang, C.-L. Zou, G.-C. Guo, and C.-H. Dong*, “Dissipatively Controlled Optomechanical Interaction via Cascaded Photon-Phonon Coupling,” Phys. Rev. Lett. 126, 163604 (2021).

7.       Y. Chen#, Y.-L. Zhang#, Z. Shen#, C.-L. Zou*, G.-C. Guo, and C.-H. Dong*, “Synthetic gauge field in a single optomechanical resonator,” Phys. Rev. Lett. 126, 123603 (2021).

8.       W. Fu#, Z. Shen#, Y.-T. Xu, C.-L. Zou, R.-S. Cheng, X. Han, and H. X. Tang*, “Phononic integrated circuitry and spin-orbit interaction of phonons,” Nat. Commun. 10, 2743 (2019).

9.       Z. Shen#, Y.-L. Zhang#, Y. Chen#, F.-W. Sun*, X.-B. Zou, G.- C. Guo, C.-L. Zou*, and C.-H. Dong*, “Reconfigurable optomechanical circulator and directional amplifier,” Nat. Commun. 9, 1797 (2018).

10.    Zhen Shen, Yan-Lei Zhang, Yuan Chen, Chang-Ling Zou*, Yun-Feng Xiao, Xu-Bo Zou, Fang-Wen Sun, Guang-Can Guo and Chun-Hua Dong*, "Experimental realization of optomechanically induced non-reciprocity," Nat. Photon. 10, 657 (2016)

11.    Chun-Hua Dong#*, Zhen Shen#, Chang-Ling Zou*, Yan-Lei Zhang, Wei Fu, and Guang-Can Guo, "Brillouin-scattering-induced transparency and non-reciprocal light storage," Nat. Commun. 6, 6193 (2015).

News & Views

1.       Z. Shen, C.-H. Dong*, “Femtosecond laser writes broadband miniaturized isolator,” Nat. Photon. 19, 224 (2025).

2.       Z. Shen, C.-H. Dong*, “Phonon counting boosts hybrid quantum networks based on optomechanics,” Sci. China: Phys. Mech. Astron. 62, 010331 (2019).

Book Chapters & Reviews

1.       Chapter: “Non-reciprocity in Optomechanical Resonators,” Z. Shen, Y. Chen, C.-L. Zou and C.-H. Dong*, Ultra-High-Q Optical Microcavities, pp. 125-158 (2020).

2.       汪昱, 舒方杰*, 沈镇, 柴诚哲, 张延磊, 董春华, 邹长铃, “基于回音壁微腔的非互易光子器件,” 科学通报67, 3372 (2022).