[1] XIONG Yuzan, INMAN J, LI Zhengyi et al. Tunable magnetically induced transparency spectra in magnon-magnon coupled Y3Fe5O12/permalloy bilayers[J]. Physical Review Applied, 17, 044010(2022).

[2] WANG Yipu, ZHANG Guoqiang, ZHANG Dengke et al. Bistability of cavity magnon polaritons[J]. Physical Review Letters, 120, 057202(2018).

[3] ALLEN L, BEIJERSBERGEN M W, SPREEUW R J C et al. Orbital angular momentum of light and the transformation of Laguerre-Gaussian laser modes[J]. Physical Review A, 45, 8185(1992).

[4] 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).

[5] BUTSCH A, KOEHLER J R, NOSKOV R E et al. CW-pumped single-pass frequency comb generation by resonant optomechanical nonlinearity in dual-nanoweb fiber[J]. Optica, 1, 158-164(2014).

[6] HUEBL H, ZOLLITSCH C W, LOTZE J et al. High cooperativity in coupled microwave resonator ferrimagnetic insulator hybrids[J]. Physical Review Letters, 111, 127003(2013).

[7] GORYACHEV M, FARR W G, CREEDON D L et al. High-cooperativity cavity QED with magnons at microwave frequencies[J]. Physical Review Applied, 2, 054002(2014).

[8] LACHANCE QUIRION D, TABUCHI Y, GLOPPE A et al. Hybrid quantum systems based on magnonics[J]. Applied Physics Express, 12, 070101(2019).

[9] SHUI Tao, YANG Wenxing, CHENG Mutian et al. Optical nonreciprocity and nonreciprocal photonic devices with directional four-wave mixing effect[J]. Optics Express, 30, 6284-6299(2022).

[10] ZHANG Xufeng, ZOU Changling, JIANG Liang et al. Cavity magnomechanics[J]. Science Advances, 2, 150128(2016).

[11] AGARWAL G S, HUANG S. Electromagnetically induced transparency in mechanical effects of light[J]. Physical Review A, 81, 041803(2010).

[12] KONG Cui, WANG Bao, LIU Zengxing et al. Magnetically controllable slow light based on magnetostrictive forces[J]. Optics Express, 27, 5544-5556(2019).

[13] LIAO Qinghong, PENG Kun, QIU Haiyan. Tunable magnomechanically induced transparency and fast-slow light in a hybrid cavity magnomechanical system[J]. Chinese Physics B, 32, 054205(2023).

[14] ULLAH K, NASEEM M T, MÜSTECAPLIOĞLU Ö E. Tunable multiwindow magnomechanically induced transparency, Fano resonances, and slow-to-fast light conversion[J]. Physical Review A, 102, 033721(2020).

[15] SINHA K P, UPADHYAYA U N. Phonon-magnon interaction in magnetic crystals[J]. Physical Review, 127, 432(1962).

[16] DEMOKRITOV S O, HILLEBRANDS B, SLAVIN A N. Brillouin light scattering studies of confined spin waves: linear and nonlinear confinement[J]. Physics Reports, 348, 441-489(2001).

[17] LU Tianxiang, ZHANG Huilai, ZHANG Qian et al. Exceptional-point-engineered cavity magnomechanics[J]. Physical Review A, 103, 063708(2021).

[18] KRAUSS T F. Why do we need slow light？[J]. Nature Photonics, 2, 448-450(2008).

[19] CHENG Guangling, ZHONG Wenxue, CHEN Aixi. Phonon induced phase grating in quantum dot system[J]. Optics Express, 23, 9870-9880(2015).

[20] TUCKER R S, KU P C, CHANG HASNAIN C J. Slow-light optical buffers: capabilities and fundamental limitations[J]. Journal of Lightwave Technology, 23, 4046(2005).

[21] KONG Cui, XIONG Hao, WU Ying. Magnon-induced nonreciprocity based on the magnon Kerr effect[J]. Physical Review Applied, 12, 034001(2019).

[22] HOU Baocheng, CHEN Huajun. Coherent optical transmission in magneto-optomechanical systems enhanced by auxiliary cavity[J]. Chinese Journal of Lasers, 50, 0612001(2023).

[23] WANG Xin, HUANG Kaiwei, XIONG Hao. Nonreciprocal sideband responses in a spinning microwave magnomechanical system[J]. Optics Express, 31, 5492-5506(2023).

[24] HUAI Sainan, LIU Yulong, ZHANG Jing et al. Enhanced sideband responses in a PT-symmetric-like cavity magnomechanical system[J]. Physical Review A, 99, 043803(2019).

[25] LI Jie, ZHU Shiyao, AGARWAL G S. Magnon-photon-phonon entanglement in cavity magnomechanics[J]. Physical Review Letters, 121, 203601(2018).

[26] ZHANG Guoqiang, YOU J Q. Higher-order exceptional point in a cavity magnonics system[J]. Physical Review B, 99, 054404(2019).

[27] LI Jie, GRÖBLACHER S. Entangling the vibrational modes of two massive ferromagnetic spheres using cavity magnomechanics[J]. Quantum Science and Technology, 6, 024005(2021).

[28] LIU Zengxing, XIONG Hao, WU Ying. Magnon blockade in a hybrid ferromagnet-superconductor quantum system[J]. Physical Review B, 100, 134421(2019).

[29] LI Jie, WANG Yipu, YOU Jianqiang et al. Squeezing microwaves by magnetostriction[J]. Physical Review A, 102, 036523(2021).

[30] ZHANG Zhedong, SCULLY M O, AGARWAL G S. Quantum entanglement between two magnon modes via Kerr nonlinearity driven far from equilibrium[J]. Physical Review Research, 1, 023021(2019).

[31] QIAN Hang, FAN Zhiyuan, LI Jie. Entangling mechanical vibrations of two massive ferrimagnets by fully exploiting the nonlinearity of magnetostriction[J]. Quantum Science and Technology, 8, 015022(2022).

[32] HUSSAIN B, QAMAR S, IRFAN M. Entanglement enhancement in cavity magnomechanics by an optical parametric amplifier[J]. Physical Review A, 105, 063704(2022).

[33] AGARWAL G S, HUANG S. Strong mechanical squeezing and its detection[J]. Physical Review A, 93, 043844(2016).

[34] ZHANG Xuefeng, ZOU Changling, JIANG Liang et al. Strongly coupled magnons and cavity microwave photons[J]. Physical Review Letters, 113, 156401(2014).

[35] YANG Rongguo, LI Ni, ZHANG Jing et al. Enhanced entanglement of two optical modes in optomechanical systems via an optical parametric amplifier[J]. Journal of Physics B: Atomic, Molecular and Optical Physics, 50, 085502(2017).

[36] HARDER M, YANG Ying, YAO Bimu et al. Level attraction due to dissipative magnon-photon coupling[J]. Physical Review Letters, 121, 137203(2018).

[37] YAO Bimu, GUI Yongsheng, XIAO Yang et al. Theory and experiment on cavity magnon-polariton in the one-dimensional configuration[J]. Physical Review B, 92, 184407(2015).