姓名：王洪福

学历：博士研究生

Email：hfwang@ybu.edu.cn

职称职务：二级教授 校长

研究方向：量子物理学、量子光学、量子计算与量子信息

▏获奖荣誉

1. 国务院政府特殊津贴专家（2023年）

2. 吉林省突出贡献奖励人才（2023年）

3. 吉林省高层次人才分类B类人才（国家级领军人才）（2023年）

4. 吉林省长白山人才工程科技创新领军人才--长白山学者（2021年）

5. 国家优秀青年科学基金获得者（2018年）

6. 第七批“吉林省拔尖创新人才”第一层次人选（2019年）

7. 第五批“吉林省拔尖创新人才”第二层次人选（2015年）

8. 吉林省中青年科技创新领军人才（2015年）

9. 第十三批“吉林省有突出贡献的中青年专业技术人才”（2014年）

10.第三批“吉林省高校新世纪科学技术优秀人才”（2013年）

11.第三批“吉林省拔尖创新人才”第三层次人选（2012年）

12.首批“吉林省高校科研春苗人才”（2012年）

13.东北师范大学兼职教授、兼职博士生导师

14.吉林省量子光学与物态调控重点实验室主任

15.吉林省量子物理基础学科研究中心主任

16.吉林省量子计算与量子信息重点实验室主任

17.吉林省量子计算与量子信息科研创新团队带头人

18.吉林省量子信息技术工程实验室主任

▏社会兼职

政协吉林省第十三届委员会，委员

十三届吉林省青联常委、副主席

▏科研项目

[1] 吉林省杰出青年科学基金项目，拓扑光子晶格系统中多体量子输运与纠缠分发研究，60万，2024.01--2026.12，主持人；

[2] 国家自然科学基金面上项目，基于超导电路晶格系统拓扑量子信息处理的研究，52万，2024.01--2027.12，主持人；

[3] 国家自然科学基金面上项目，腔光机械阵列系统的多体量子效应及拓扑性质研究，63万，2021.01--2024.12，主持人；

[4] 国家优秀青年科学基金项目，量子信息学，130万，2019.01--2021.12，主持人；

[5] 吉林省长白山人才工程科技创新领军人才-长白山学者，50万，2022.01--2026.12；

[6] 国家自然科学基金地区基金，噪声环境下腔量子电动力学量子计算与量子相干操控的理论研究，62万，2015.01--2018.12，主持人；

[7] 国家自然科学基金地区基金，基于半导体量子点-光学微腔耦合系统量子信息处理的研究，50万，2013.01--2016.12，主持人；

[8] 国家自然科学基金专项基金，量子算法及其在量子信息处理中的应用研究，5万，2012.01--2012.12，主持人；

[9] 吉林省量子计算与量子信息科研创新团队建设经费，200万，2019.05--2024.05，负责人；

[10] 中国博士后科学基金面上项目，半导体量子点量子计算理论研究，5万，2012.11--2013.10，主持人；

[11] 吉林省中青年科技创新领军人才及团队项目，吉林省量子计算与量子信息科研创新团队，15万，2016.01--2018.12，主持人；

[12] 吉林省教育厅“首批吉林省高校科研春苗人才”项目，基于半导体量子点量子计算与量子信息处理的研究，2万，2013.01--2014.12，主持人；

[13] 吉林省教育厅第三批“吉林省高校新世纪科学技术优秀人才”计划专项项目，基于腔QED和电路QED量子信息处理的研究，4万，2014.01--2015.12，主持人；

▏代表性成果

学术论文

[1] Jing-Yu Zhang, Ke-Yu Shi, Zuan Meng, Rui Hou, Xue Han*, Hong-Fu Wang*, and Shou Zhang*, Nonreciprocal quantum heat engine in a spinning optomechanical system, Physical Review A 2025, 111(2): 022216.

[2] Zhi-Xu Zhang, Kai-Xin Hu, Yu Yan, Yu Zhang*, Shutian Liu*, Ji Cao, Wen-Xue Cui, Shou Zhang*, and Hong-Fu Wang*, Generalized topological phase transition threshold and the enhanced dynamics in dissipatively coupled lattices, New Journal of Physics 2025, 27(5): 053005.

[3] Rui Hou (侯瑞), Wei Zhang (张微), Xue Han (韩雪)*, Hong-Fu Wang (王洪福)*, and Shou Zhang (张寿)*, Generation of High-Quality Single-Photon Sources in Cavity Optomagnonics, Chinese Physics Letters 2025, 42(1): 014203.

[4] Xuan Ma, Yikyung Yu, Xue Han*, Hong-Fu Wang*, and Shou Zhang*, Enhanced electromechanical entanglement in a coupled optoelectromechanical system, Physical Review A 2025, 111(3): 033503.

[5] Xiao-Wei He, Zheng-Yang Wang, Xue Han*, Hong-Fu Wang*, and Shou Zhang*, Nonreciprocal magnon laser in a spinning cavity optomagnonic system, Optics Letters 2025, 50(2): 499-502.

[6] Zhi-Xu Zhang, Kai-Xin Hu, Liang Wang, Yu Zhang*, Shutian Liu*, Shou Zhang, and Hong-Fu Wang*. Generalized Anderson localization threshold in dissipatively coupled quasicrystals, Physical Review B 2024, 110(16): 165425.

[7] Hao-Tian Wu, Ping-Chi Ge, Xue Han*, Hong-Fu Wang*, and Shou Zhang*,  Nonreciprocal mechanical squeezing in cavity magnomechanics, EPJ Quantum Technology 2024, 11(): 88.

[8] Jie Zhang, Kai-Xin Hu, Chun-Lin Zhang, Xiao-Feng Nie, Zhi-Xu Zhang, Yu Yan, Ji Cao*, Shou Zhang*, and Hong-Fu Wang*, PT -symmetry phase transition and unidirectional accumulation of eigenstates in non-Hermitian system with a single impurity, Physical Review A 2024, 110(6): 062216.

[9] Shao-Jun Cao, Li-Na Zheng, Liu-Yong Cheng*, and Hong-Fu Wang*, Controllable entangled-state transmission in a non-Hermitian trimer Su-Schrieffer-Heeger chain, Physical Review A 2024, 110(6): 062409.

[10] Wei Zhang, Rui Hou, Tie Wang, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Simultaneous nonreciprocal photon blockade via directional parametric amplification, Physical Review A 2024, 110(2): 023723.

[11] Si-Yu Guan, Hong-Fu Wang*, and Xuexi Yi*. Manipulation of tunable nonreciprocal entanglement and one-way steering induced by two-photon driving,  Physical Review A 2024, 109(6): 062423.

[12] Wei Zhang, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Magnon blockade induced by parametric amplification, Physical Review A 2024, 109(4): 043712.

[13] Xiao-Feng Nie, Ye-Wei-Yi Li, Wen-Xue Cui*, Shou Zhang*, and Hong-Fu Wang*. Non-Bloch symmetry and topological phase transition in one-dimensional nonreciprocal topolectrical circuits, Physical Review A 2024, 109(2): 022241.

[14] Rui Hou, Wei Zhang, Xue Han*, Hong-Fu Wang*, and Shou Zhang*. Magnon blockade based on the Kerr nonlinearity in cavity electromagnonics, Physical Review A 2024, 109(3): 033721.

[15] Kai-Xin Hu, Yu Yan, Zhi-Xu Zhang, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Boundary criticality of Chern insulator in two-dimensional Su-Schrieffer-Heeger model with next-nearest-neighbor hopping, Physical Review A 2024, 109(2): 022211.

[16] Jia-Jie Li, Jing-Quan Li, Yu Yan, Ji Cao*, Wen-Xue Cui*, Shou Zhang, and Hong-Fu Wang*.  Topological semimetal phase in non-Hermitian Su-Schrieffer-Heeger model, New Journal of Physics 2024, 26(2): 023012.

[17] Xue-Dong Zhao, Yan Xing, Ji Cao, Wen-Xue Cui, Shutian Liu*, and Hong-Fu Wang*.  Witnessing edge modes in trimerized circuit quantum electrodyamic lattice, New Journal of Physics 2024, 26(2): 023037.

[18] Xuedong Zhao, Yan Xing, Ji Cao, Shutian Liu*, Wen-Xue Cui*, and Hong-Fu Wang*. Engineering quantum diode in one-dimensional time-varying superconducting circuits, npj Quantum Information 2023, 9(1): 59.

[19] Yu Yan, Wen-Xue Cui, Shutian Liu*, Ji Cao*, Shou Zhang, and Hong-Fu Wang*. Topological phase in a nonreciprocal Kitaev chain. New Journal of Physics 2023, 25(12): 123023.

[20] Zhi-Xu Zhang, Ji Cao, Wen-Xue Cui, Yu Zhang*, Shou Zhang*, and Hong-Fu Wang*. Detachment between edge and skin states in non-Hermitian lattice. Physical Review A 2023, 108(5): 052210.

[21] Li-Na Zheng, Hong-Fu Wang*, and Xuexi Yi*. Planar and tunable quantum state transfer in a splicing Y-junction Su-Schrieffer-Heeger chain. New Journal of Physics. 2023, 25(11): 113003.

[22] Wen-Jie Geng, Ya-Jun Wang, Zhi-Xu Zhang, Ji Cao*, Wen-Xue Cui*, and Hong-Fu Wang*. Separable zero energy topological edge states and nonzero energy gap state in the nonreciprocal Su-Schrieffer-Heeger model. Physical Review B 2023, 108(14): 144109.

[23] Zhi-Xu Zhang, Ji Cao, Jing-Quan Li, Yu Zhang*, Shutian Liu*, Shou Zhang, and Hong-Fu Wang*. Topological skin modes and intensity amplification in nonlinear non-Hermitian lattice. Physical Review B 2023, 108(12): 125402.

[24] Lu Qi*, Ai-Lei He, Hong-Fu Wang*, and Yongjun Liu*. Topological semimetal phase and dynamical characterizationin a non-Hermitian two-leg ladder model, Physical Review B 2023, 107(11): 115107.

[25] Liang Wang, Wei Zhang, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Simultaneous cooling and synchronization of the mechanical and the  radio-frequency resonators via voltage modulation. EPJ Quantum Technology 2023, 10(1): 34.

[26] Yu-Mu Liu, Jing Cheng, Hong-Fu Wang*, and Xuexi Yi*. Simultaneous nonreciprocal conventional photon blockades of two independent optical modes by a two-level system. Physical Review A 2023, 107(6): 063701.

[27] Lu Qi*, Ning Han, Shutian Liu, Hong-Fu Wang*, and Ai-Lei He*. Controllable excitation transmission and topological switch based on an imaginary topological channel in a non-Hermitian Su-Schrieffer-Heeger chain. Physical Review A 2023, 107(6): 062214.

[28] Tie Wang, Wei Zhang, Ji Cao, and Hong-Fu Wang*. Exceptional-point-engineered phonon laser in a cavity magnomechanical system. New Journal of Physics 2023, 25(8): 083045.

[29] Chang-Mei Zheng, Wei Zhang, Dong-Yang Wang, Xue Han*, and Hong-Fu Wang*. Simultaneously enhanced photon blockades in two microwave cavities via driving a giant atom, New Journal of Physics 2023, 25(4): 043030.

[30] Wei Zhang, Tie Wang, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Nonreciprocal photon blockade in a spinning resonator coupled to two two-level atoms. Science China-Physics Mechanics & Astronomy 2023, 66(4): 240313.

[31] Tie Wang, Xue Han, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Optomechanically Induced Faraday Effect with Mechanical Driving and Coulomb Coupling. Advanced Quantum Technologies 2023, 6(7): 2200162.

[32] Ying-Li Liu, Yan-Qiang Ji, Xue Han, Wen-Xue Cui*, Shou Zhang, and Hong-Fu Wang*. Fast Conversion of Three-Particle Dicke States to Four-Particle Dicke States with Rydberg Superatoms. Advanced Quantum Technologies 2023, 6(4): 2200173.

[33] Si-Yu Guan, Hong-Fu Wang*, and Xuexi Yi*. Cooperative-effect-induced one-way steering in open cavity magnonics,  npj Quantum Information 2022, 8(1): 102.

[34] Li-Na Zheng, Xuexi Yi*, and Hong-Fu Wang*. Engineering the phase-robust topological hub in a chiral-symmetric dimerized superconducting circuit lattice with long-range hopping, Physical Review Applied 2022, 18(5): 054307.

[35] Yan Xing, Lu Qi, Xuedong Zhao, Zhe Lv*, Shutian Liu, Shou Zhang*, and Hong-Fu Wang*. Quantum transport in a one-dimensional quasicrystal with mobility edges, Physical Review A 2022, 105(3): 032443.

[36] Tian-Qi Zhang, Dong-Yang Wang, Cheng-Hua Bai, Shou Zhang*, and Hong-Fu Wang*. Dissipative Generation of Two-Mode Mechanical Squeezing via Frequency Modulation, Advanced Quantum Technologies 2022, 5(2) 2100113.

[37] Chao Chen, Lu Qi, Yan Xing, Wen-Xue Cui*, Shou Zhang, and Hong-Fu Wang*. General bounded corner states in two-dimensional off-diagonal Aubry-André-Harper model with flat bands. New Journal of Physics 2021, 23(12): 123008.

[38] Qi Guo*, Wen-Jie Zhang, Gang Li, Tiancai Zhang*, Hong-Fu Wang, and Shou Zhang. Modified quantum delayed-choice experiment without quantum control or entanglement assistance, Physical Review A 2021, 104(2): 022210.

[39] Kai-Xin Hu, Chao Chen, Lu Qi, Wen-Xue Cui*, Shou Zhang, and Hong-Fu Wang*. Topological phase transition and detectable edge state in a quasi-three-dimensional circuit quantum electrodynamic lattice, Physical Review A 2021, 104(2): 023707.

[40] Xuedong Zhao, Yan Xing, Lu Qi, Shutian Liu*, Shou Zhang, and Hong-Fu Wang*. Real-potential-driven anti-PT-symmetry breaking in non-Hermitian Su-Schrieffer-Heeger model, New Journal of Physics 2021, 23(7): 073043.

[41] Tie Wang, Cheng-Hua Bai, Dong-Yang Wang, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Optomechanically induced Faraday and splitting effects in a double-cavity optomechanical system, Physical Review A 2021, 104(1): 013721.

[42] Lu Qi, Yu Yan, Yan Xing, Xue-Dong Zhao, Shutian Liu*, Wen-Xue Cui, Xue Han, Shou Zhang*, and Hong-Fu Wang*. Topological router induced via long-range hopping in a Su-Schrieffer-Heeger chain, Physical Review Research 2021, 3(2): 023037.

[43] Cheng-Hua Bai, Dong-Yang Wang, Lu Qi, Yan Xing, and Hong-Fu Wang*. Cavity optomechanical system--a powerful platform for investigating quantum effects, Fundamental Research 2021, 1(2): 217-219 (Invited Perspectives).

[44] Lu Qi, Yan Xing, Xue-Dong Zhao, Shutian Liu*, Shou Zhang*, Shi Hu, and Hong-Fu Wang*. Topological beam splitter via defect-induced edge channel in Rice-Mele model, Physical Review B 2021, 103(8): 085129.

[45] Cheng-Hua Bai, Dong-Yang Wang,  Shou Zhang*, Shutian Liu, and Hong-Fu Wang*. Double-mechanical-oscillator cooling of breaking the restrictions of quantum backaction and frequency ratio via dynamical modulation, Physical Review A 2021, 103(3) 033508.

[46] Ji Cao, Wen-Xue Cui, X. X. Yi*, and Hong-Fu Wang*. Controllable photon-phonon conversion via the topologically protected edge channel in an optomechanical lattice, Physical Review A 2021, 103(2): 023504.

[47] Cheng-Hua Bai, Dong-Yang Wang,  Shou Zhang*, Shutian Liu, and Hong-Fu Wang*. Generation of Strong Mechanical-Mechanical Entanglement by Pump Modulation, Advanced Quantum Technologies 2021, 4(5) 2000149. (Advanced Science News (ASN China) 专题报道)

[48] Lu Qi, Guo-Li Wang, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Dissipation-induced topological phase transition and periodic-driving-induced photonic topological state transfer in a small optomechanical lattice, Frontiers of Physics 2021, 16(1): 12503.

[49] Lu Qi, Guo-Li Wang, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Robust interface-state laser in non-Hermitian micro-resonator arrays, Physical Review Applied 2020, 13(6): 064016.

[50] Dong-Yang Wang, Cheng-Hua Bai, Yan Xing, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Enhanced photon blockade via driving a trapped Lambda-type atom in a hybrid optomechanical system, Physical Review A 2020, 102(4): 043705.

[51] Ji Cao, X. X. Yi*, and Hong-Fu Wang*.Band structure and exceptional ring in a two-dimensional superconducting circuit lattice, Physical Review A 2020, 102(3): 032619.

[52] Dong-Yang Wang, Cheng-Hua Bai, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*.Photon blockade in a double-cavity optomechanical system with nonreciprocal coupling, New Journal of Physics 2020, 22(9): 093006.

[53] Lu Qi, Guo-Li Wang, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Engineering the topological state transfer and topological beam splitter in an even-sized Su-Schrieffer-Heeger chain, Physical Review A 2020, 102(2): 022404.

[54] Li-Na Zheng, Lu Qi, Liu-Yong Cheng*, Hong-Fu Wang*, and Shou Zhang. Defect-induced controllable quantum state transfer via topologically protected channel in flux qubit chain, Physical Review A 2020, 102(1): 012606.

[55] Lu Qi, Yan Xing, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Topological phase induced by distinguishing parameter regimes in cavity optomechanical system with multiple mechanical resonators, Physical Review A 2020, 101(5): 052325.

[56] Cheng-Hua Bai, Dong-Yang Wang, Shou Zhang*, Shutian Liu, and Hong-Fu Wang*. Strong mechanical squeezing in a standard optomechanical system by pump modulation, Physical Review A 2020, 101(5): 053836.

[57] Dong-Yang Wang, Cheng-Hua Bai, Xue Han, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*, Enhanced photon blockade in an optomechanical system with parametric amplification, Optics Letters 2020, 45(9): 2604-2607.

[58] Lu Qi, Guo-Li Wang, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Controllable photonic and phononic topological state transfers in a small optomechanical lattice, Optics Letters, 2020, 45(7): 2018-2021.

[59] Cheng-Hua Bai, Dong-Yang Wang, Shou Zhang*, Shutian Liu, and Hong-Fu Wang*. Engineering of strong mechanical squeezing via the joint effect between Duffing nonlinearity and parametric pump driving, Photonics Research 2019, 7(11): 1229-1239.

[60] Lu Qi, Yu Yan, Guo-Li Wang*, Shou Zhang*, and Hong-Fu Wang*. Bosonic Kitaev phase in a frequency-modulated optomechanical array, Physical Review A 2019, 100(6): 062323.

[61] Dong-Yang Wang, Cheng-Hua Bai, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Distinguishing photon blockade in a PT -symmetric optomechanical system, Physical Review A 2019, 99(4): 043818.

[62] Xue Han, Dong-Yang Wang, Cheng-Hua Bai, Wen-Xue Cui, Shou Zhang*, and Hong-Fu Wang*. Mechanical squeezing beyond resolved sideband and weak-coupling limits with frequency modulation, Physical Review A 2019, 100(3): 033812.

[63] Dong-Yang Wang, Cheng-Hua Bai, Shutian Liu*, Shou Zhang*, and Hong-Fu Wang*. Optomechanical cooling beyond the quantum backaction limit with frequency modulation, Physical Review A 2018, 98(2): 023816.

[64] Yan Xing, Lu Qi, Ji Cao, Dong-Yang Wang, Cheng-Hua Bai, Hong-Fu Wang*, Ai-Dong Zhu, and Shou Zhang, Spontaneous PT-symmetry breaking in  non-Hermitian coupled-cavity array, Physical Review A 2017, 96(4): 043810. （PRA Kaleidoscope）

[65] Qi Guo, Shuqin Zhai, Liu-Yong Cheng, Hong-Fu Wang, and Shou Zhang. Counterfactual quantum cloning without transmitting any physical particles, Physical Review A 2017, 96(5): 052335.

[66] Shi-Lei Su, Qi Guo, Hong-Fu Wang, and Shou Zhang. Simplified scheme for entanglement preparation with Rydberg pumping via dissipation, Physical Review A 2015, 92: 022328.

[67] Shi-Lei Su, Xiao-Qiang Shao, Hong-Fu Wang, and Shou Zhang. Scheme for entanglement generation in an atom-cavity system via dissipation, Physical Review A2014, 90(5): 054302.

[68] Qi Guo, Liu-Yong Cheng, Li Chen, Hong-Fu Wang, and Shou Zhang. Counterfactual distributed controlled-phase gate for quantum-dot spin qubits in double-sided optical microcavities, Physical Review A 2014, 90(4): 042327.

[69] Qi Guo, Juan Bai, Liu-Yong Cheng, Xiao-Qiang Shao, Hong-Fu Wang, Shou Zhang. Simplified optical quantum-information processing via weak cross-Kerr nonlinearities, Physical Review A 2011, 83(5):054303

[70] Xiao-Qiang Shao, Hong-Fu Wang, Li Chen, Shou Zhang, Yong-Fang Zhao, Kyu-Hwang Yeon. One-step implementation of the 1→3 orbital state quantum cloning machine via quantum Zeno dynamics, Physical Review A 2009, 80(6), 062323

[71] Hong-Fu Wang, Shou Zhang. Linear optical generation of multipartite entanglement with conventional photon detectors, Physical Review A 2009, 79(4): 042336.

[72] Hong-Fu Wang*, Ai-Dong Zhu, Shou Zhang, and Kyu-Hwang Yeon, Optically controlled phase gate and teleportation of a controlled-NOT gate for spin qubits in quantum dot-microcavity coupled system, Physical Review A 2013, 87(6): 062337.

[73] Hong-Fu Wang*, Ai-Dong Zhu, Shou Zhang, Kyu-Hwang Yeon. Simple implementation of discrete quantum Fourier transform via cavity quantum electrodynamics, New Journal of Physics 2011, 13(1): 013021

[74] Hong-Fu Wang*, Ai-Dong Zhu, and Shou Zhang. One-step implementation of a multiqubit phase gate with one control qubit and multiple target qubits in coupled cavities, Optics Letters, 2014, 39(6): 1489-1492.

[75] Hong-Fu Wang*, Shou Zhang, Ai-Dong Zhu, X. X. Yi, Kyu-Hwang Yeon. Local conversion of four Einstein-Podolsky-Rosen photon pairs into four-photon polarization-entangled decoherence-free states with non-photon-number-resolving detectors, Optics Express. 2011, 19(25): 25433-25440.

[76] Hong-Fu Wang*, Ai-Dong Zhu, and Shou Zhang, Physical optimization of quantum error correction circuits with spatially separated quantum dot spins, Optics Express 2013, 21(10): 12484-12494.

[77] Xiao-Qiang Shao, Hong-Fu Wang, Li Chen, Shou Zhang, Yong-Fang Zhao, Kyu-Hwang Yeon. Converting two-atom singlet state into three-atom singlet state via quantum Zeno dynamics, New Journal of Physics 2010, 12(2): 023040.

[78] Lu Qi, Yan Xing, Hong-Fu Wang*, Ai-Dong Zhu, and Shou Zhang. Simulating Z2 topological insulators via a one-dimensional cavity optomechanical cells array, Optics Express 2017, 25(15): 17948-17959.

[79] Yu-Mu Liu, Cheng-Hua Bai, Dong-Yang Wang, Tie Wang, Ming-Hua Zheng, Hong-Fu Wang*, Ai-Dong Zhu, and Shou Zhang. Ground-state cooling of  rotating mirror in double-Laguerre-Gaussian-cavity with atomic ensemble, Optics Express. 2018, 26(5): 6143-6157.

[80] Yan Xing, Lu Qi, Ji Cao, Dong-Yang Wang, Cheng-Hua Bai,Wen-Xue Cui, Hong-Fu Wang*, Ai-Dong Zhu, and Shou Zhang. Controllable photonic and phononic edge  locolization via optomechanically induced Kitaev phase, Optics Express. 2018, 26(13): 16250-16264.

[81] Cheng-Hua Bai, Dong-Yang Wang, Shou Zhang*, and Hong-Fu Wang*. Qubit-assisted squeezing of the mirror motion in a dissipative optomechanical cavity system, Science China-Physics Mechanics & Astronomy. 2019, 62(7): 970311.（ESI高被引论文1%）.

[82] Lu Qi, Yan Xing, Ji Cao, Xin-Xin Jiang, Cheng-Shou An, Ai-Dong Zhu, Shou Zhang, and Hong-Fu Wang*. Simulation and detection of the topological properties of a modulated Rice-Mele model in a one-dimensional circuit-QED lattice, Science China-Physics Mechanics & Astronomy. 2018, 61(8): 080313.

[83] Zhi-Xin Yang, Liang Wang, Yu-Mu Liu, Dong-Yang Wang, Cheng-Hua Bai, Shou Zhang*, and Hong-Fu Wang*. Ground state cooling of magnomechanical resonator in PT-symmetric cavity magnomechanical system at room temperature, Frontiers of Physics 2020, 15(5): 52504.

[84] Yang Jiao, Cheng-Hua Bai, Dong-Yang, Shou Zhang, and Hong-Fu Wang*. Optical nonreciprocal response and conversion in a Tavis-Cummings coupling optomechanical system, Quantum Engineering 2020, 2(2): e39.

知识产权

[1] 王洪福，张寿，朱爱东，崔文学，白成华，王东阳，远距离多节点间分布式量子中继器，ZL201621273643.4.