[1] Lu F. Controllable quantum entanglement based on cavity structure. Laser & Optoelectronics Progress, 56, 042701(2019).

[2] Lin J. Preparing Bell state by using dissipative process in directly coupled cavities. Laser & Optoelectronics Progress, 56, 242703(2019).

[3] Chen C, Wu D W, Yang C Y et al. Research on enhancing synchronization precision between Roland C stations based on cavity electro-opto-mechanical system. Acta Optica Sinica, 39, 0827001(2019).

[4] Kippenberg T J, Vahala K J. Cavity optomechanics： back-action at the mesoscale. Science, 321, 1172-1176(2008).

[5] Weis S, Rivière R, Deléglise S et al. Optomechanically induced transparency. Science, 330, 1520-1523(2010).

[6] Agarwal G S, Huang S M. Electromagnetically induced transparency in mechanical effects of light. Physical Review A, 81, 041803(2010).

[7] Wang J, Tian X D, Liu Y M et al. Entanglement manipulation via Coulomb interaction in an optomechanical cavity assisted by two-level cold atoms. Laser Physics, 28, 065202(2018).

[8] Wang J. Optical nonreciprocity in two-cavity optomechanical system. Chinese Journal of Quantum Electronics, 37, 328-336(2020).

[9] Wang J. The optical nonreciprocal response based on a four-mode optomechanical system. Chinese Physics B, 29, 034210(2020).

[10] Ma P C, Zhang J Q, Xiao Y et al. Tunable double optomechanically induced transparency in an optomechanical system. Physical Review A, 90, 043825(2014).

[11] Yan X B, Yan X B, Deng Z J et al. Entanglement optimization of filtered output fields in cavity optomechanics. Optics Express, 27, 24393-24402(2019).

[12] Yan X B, Yang L, Tian X D et al. Optomechanically induced transparency and normal mode splitting in an optical parametric amplifier cavity. Acta Physica Sinica, 63, 204201(2014).

[13] Zhang L W, Li X L, Yang L. Optical nonreciprocity with blue-detuned driving in two-cavity optomechanics. Acta Physica Sinica, 68, 170701(2019).

[14] Gu K H, Yan X B, Zhang Y et al. Tunable slow and fast light in an atom-assisted optomechanical system. Optics Communications, 338, 569-573(2015).

[15] Guo Y J, Li K, Nie W J et al. Electromagnetically-induced-transparency-like ground-state cooling in a double-cavity optomechanical system. Physical Review A, 90, 053841(2014).

[16] Liu Y M, Bai C H, Wang D Y et al. Ground-state cooling of rotating mirror in double-Laguerre-Gaussian-cavity with atomic ensemble. Optics Express, 26, 6143-6157(2018).

[17] Li L C, Luo R H, Liu L J et al. Double-passage ground-state cooling induced by quantum interference in the hybrid optomechanical system. Scientific Reports, 8, 14276(2018).

[18] Jia W Z, Wei L F, Li Y et al. Phase-dependent optical response properties in an optomechanical system by coherently driving the mechanical resonator. Physical Review A, 91, 043843(2015).

[19] He B, Yang L, Jiang X S et al. Transmission nonreciprocity in a mutually coupled circulating structure. Physical Review Letters, 120, 203904(2018).

[20] Liu T T, Lin G W, Hao Y M et al. Interaction-free all-optical switching in coupled cavities. Journal of East China University of Science and Technology （Natural Science Edition）, 44, 448-453(2018).

[21] Xu X W, Song L N, Zheng Q et al. Optomechanically induced nonreciprocity in a three-mode optomechanical system. Physical Review A, 98, 063845(2018).

[22] Lü H, Jiang Y J, Wang Y Z et al. Optomechanically induced transparency in a spinning resonator. Photonics Research, 5, 367(2017).

[23] Wu Q. Tunable ponderomotive squeezing induced by Coulomb interaction in an optomechanical system. Chinese Physics B, 25, 010304(2016).

[24] Lü X Y, Jing H, Ma J Y et al. PT-symmetry-breaking chaos in optomechanics. Physical Review Letters, 114, 253601(2015).

[25] Bai C, Hou B P, Lai D G et al. Tunable optomechanically induced transparency in double quadratically coupled optomechanical cavities within a common reservoir. Physical Review A, 93, 043804(2016).

[26] Yan X B. Optomechanically induced ultraslow light， perfect transmission and absorption. （2020-05-25）［2020-08-11］. https：//arxiv.org/abs/2005.11871v1

[27] Yan X B. Optomechanically induced transparency and gain. Physical Review A, 101, 043820(2020).

[28] Wang T, Zheng M H, Bai C H et al. Normal-mode splitting and optomechanically induced absorption， amplification， and transparency in a hybrid optomechanical system. Annalen Der Physik, 530, 1800228(2018).

[29] Yan X B, Jia W Z, Li Y et al. Optomechanically induced amplification and perfect transparency in double-cavity optomechanics. Frontiers of Physics, 10, 351-357(2015).

[30] Jiang C, Song L N, Li Y. Directional phase-sensitive amplifier between microwave and optical photons. Physical Review A, 99, 023823(2019).

[31] Chen H J. Optomechanically induced transparency and nonlinear responses based on graphene optomechanics system. EPJ Quantum Technology, 6, 3(2019).

[32] Yang Q, Hou B P, Lai D G. Local modulation of double optomechanically induced transparency and amplification. Optics Express, 25, 9697-9711(2017).

[33] Liu Y L, Wu R B, Zhang J et al. Controllable optical response by modifying the gain and loss of a mechanical resonator and cavity mode in an optomechanical system. Physical Review A, 95, 013843(2017).

[34] Yan X B. Optomechanically induced ultraslow and ultrafast light. （2020-06-23）［2020-08-11］. https：//arxiv.org/abs/2006.13736