[3] Agarwal G S, Huang S M. Electromagnetically induced transparency in mechanical effects of light[J]. Physical Review A, 81, 041803(2010).
[4] Yan X B. Optomechanically induced transparency and gain[J]. Physical Review A, 101, 043820(2020).
[5] 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[J]. Annalen der Physik, 530, 1800228(2018).
[6] Yang Q, Hou B P, Lai D. Local modulation of double optomechanically induced transparency and amplification[J]. Optics Express, 25, 9697-9711(2017).
[7] Maayani S, Dahan R, Kligerman Y et al. Flying couplers above spinning resonators generate irreversible refraction[J]. Nature, 558, 569-572(2018).
[9] Jiang C, Song L N, Li Y. Directional amplifier in an optomechanical system with optical gain[J]. Physical Review A, 97, 053812(2018).
[10] He B, Yang L, Jiang X S et al. Transmission nonreciprocity in a mutually coupled circulating structure[J]. Physical Review Letters, 120, 203904(2018).
[11] Yan X B, Lu H L, Gao F et al. Perfect optical nonreciprocity in a double-cavity optomechanical system[J]. Frontiers of Physics, 14, 52601(2019).
[12] Zhang L W, Li X L, Yang L. Optical nonreciprocity with blue-detuned driving in two-cavity optomechanics[J]. Acta Physical Sinica, 68, 170701(2019).
[13] Bai C H, Wang D Y, Zhang S et al. Modulation-based atom-mirror entanglement and mechanical squeezing in an unresolved-sideband optomechanical system[J]. Annalen der Physik, 531, 1800271(2019).
[14] 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[J]. Laser Physics, 28, 065202(2018).
[15] Yan X B, Deng Z J, Tian X D et al. Entanglement optimization of filtered output fields in cavity optomechanics[J]. Optics Express, 27, 24393-24402(2019).
[16] Lu X Y, Liao J Q, Tian L et al. Steady-state mechanical squeezing in an optomechanical system via Duffing nonlinearity[J]. Physical Review A, 91, 013834(2015).
[17] Agarwal G S, Huang S M. Strong mechanical squeezing and its detection[J]. Physical Review A, 93, 043844(2016).
[18] Genes C, Ritsch H, Drewsen M et al. Atom-membrane cooling and entanglement using cavity electromagnetically induced transparency[J]. Physical Review A, 84, 051801(2011).
[19] Guo Y J, Li K, Nie W J et al. Electromagnetically-induced-transparency-like ground-state cooling in a double-cavity optomechanical system[J]. Physical Review A, 90, 053841(2014).
[20] 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[J]. Optics Express, 26, 6143-6157(2018).
[21] 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[J]. Scientific Reports, 8, 14276(2018).
[23] Liu Y C, Xiao Y F, Luan X S et al. Coupled cavities for motional ground-state cooling and strong optomechanical coupling[J]. Physical Review A, 91, 033818(2015).
[24] Lai D G, Zou F, Hou B P et al. Simultaneous cooling of coupled mechanical resonators in cavity optomechanics[J]. Physical Review A, 98, 023860(2018).
[25] Xia K Y, Evers J. Ground state cooling of a nanomechanical resonator in the nonresolved regime via quantum interference[J]. Physical Review Letters, 103, 227203(2009).
[26] Wu Q. Tunable ponderomotive squeezing induced by Coulomb interaction in an optomechanical system[J]. Chinese Physics B, 25, 010304(2016).
[27] Cohadon P F, Heidmann A, Pinard M. Cooling of a mirror by radiation pressure[J]. Physical Review Letters, 83, 3174-3177(1999).
[30] Guo Y B, Xiao Y, Yu Y F et al. Optical bistability and entanglement in a nonlinear optomechanical system[J]. Acta Optica Sinica, 35, 1027002(2015).
[31] Genes C, Vitali D, Tombesi P et al. Ground-state cooling of a micromechanical oscillator: comparing cold damping and cavity-assisted cooling schemes[J]. Physical Review A, 77, 033804(2008).
[32] Bhattacharya M, Giscard P, Meystre P. Entanglement of a Laguerre-Gaussian cavity mode with a rotating mirror[J]. Physical Review A, 77, 013827(2008).
[33] Bhattacharya M, Meystre P. Using a Laguerre-Gaussian beam to trap and cool the rotational motion of a mirror[J]. Physical Review Letters, 99, 153603(2007).
[34] Liu Y M. Study on ground state cooling of mechanical resonator based on optomechanical system[D]. Yanji: Yanbian University(2019).