Optomechanics

    1. H. Ian, Z.R. Gong, Y.X. Liu, C.P. Sun, F. Nori
      Cavity optomechanical coupling assisted by an atomic gas
      Phys. Rev. A 78, 013824 (2008). [PDF][Link][arXiv]

    2. Z.R. Gong, H. Ian, Y.X. Liu, C.P. Sun, F. Nori
      Effective Hamiltonian approach to the Kerr nonlinearity in an optomechanical system
      Phys. Rev. A 80, 065801 (2009). [PDF][Link][arXiv]

    3. Y. Chang, T. Shi, Y.X. Liu, C.P. Sun, F. Nori
      Multistability of electromagnetically induced transparency in atom-assisted optomechanical cavities
      Phys. Rev. A 83, 063826 (2011). [PDF][Link][arXiv]

    4. J.Q. Liao, F. Nori
      Photon blockade in quadratically coupled optomechanical systems
      Phys. Rev. A 88, 023853 (2013). [PDF][Link][arXiv]

    5. X.Y. Lu, W.M. Zhang, S. Ashhab, Y. Wu, F. Nori
      Quantum-criticality-induced strong Kerr nonlinearities in optomechanical systems
      Scientific Reports 3, 2943 (2013). [PDF][Link][arXiv]

    6. J.Q. Liao, F. Nori
      Spectrometric Reconstruction of Mechanical-motional States in Optomechanics
      Phys. Rev. A 90, 023851 (2014). [PDF][Link][arXiv]

    7. J.Q. Liao, F. Nori
      Single-photon quadratic optomechanics
      Scientific Reports 4, 6302 (2014). [PDF][Link][arXiv]

    8. J.Q. Liao, Q.Q. Wu, F. Nori
      Entangling two macroscopic mechanical mirrors in a two-cavity optomechanical system
      Phys. Rev. A 89, 014302 (2014). [PDF][Link][arXiv]

    9. H. Wang, X. Gu, Y.X. Liu, A. Miranowicz, F. Nori
      Optomechanical analog of two-color electromagnetically-induced transparency: Photon transmission through an optomechanical device with a two-level system
      Phys. Rev. A 90, 023817 (2014). [PDF][Link][arXiv]

    10. J.R. Johansson, G. Johansson, F. Nori
      Optomechanical-like coupling between superconducting resonators
      Phys. Rev. A 90, 053833 (2014). [PDF][Link][arXiv]

    11. X.Y. Lu, J.Q. Liao, L. Tian, F. Nori
      Steady-state mechanical squeezing in an optomechanical system via Duffing nonlinearity
      Phys. Rev. A 91, 013834 (2015). [PDF][Link][arXiv]
    12. X.Y. Lu, Y. Wu, J.R. Johansson, H. Jing, J. Zhang, F. Nori
      Squeezed Optomechanics with Phase-matched Amplification and Dissipation
      Phys. Rev. Lett. 114, 093602 (2015). [PDF][Link][arXiv]
    13. E.J. Kim, J.R. Johansson, F. Nori
      Circuit analog of quadratic optomechanics
      Phys. Rev. A 91, 033835 (2015). [PDF][Link][arXiv]

    14. H. Jing, S.K. Ozdemir, Z. Geng, J. Zhang, X.Y. Lu, B. Peng, L. Yang, F. Nori
      Optomechanically-Induced Transparency in parity-time-symmetric microresonators
      Scientific Reports 5, 9663 (2015). [PDF][Link][arXiv]
    15. J.Q. Liao, C.K. Law, L.M. Kuang, F. Nori
      Enhancement of mechanical effects of single photons in modulated two-mode optomechanics
      Phys. Rev. A 92, 013822 (2015). [PDF][Link][arXiv]
    16. H. Wang, X. Gu, Y.X. Liu, A. Miranowicz, F. Nori
      Tunable photon blockade in a hybrid system consisting of an optomechanical device coupled to a two-level system
      Phys. Rev. A 92, 033806 (2015). [PDF][Link][arXiv]
    17. M. Antognozzi, C.R. Bermingham, R.L. Harniman, S. Simpson, J. Senior, R. Hayward, H. Hoerber, M.R. Dennis, A.Y. Bekshaev, K.Y. Bliokh, F. Nori
      Direct measurements of the extraordinary optical momentum and transverse spin-dependent force using a nano-cantilever
      Nature Physics 12, 731–735 (2016). [PDF][Link][arXiv][Suppl. Info.]
      Featured in a "News and Views”: Optomechanical tomography, Nature Physics 12, 725 (2016). [PDF][Link]

    18. F. Monifi, J. Zhang, S.K. Ozdemir, B. Peng, Y.X. Liu, F. Bo, F. Nori, L. Yang
      Optomechanically induced stochastic resonance and chaos transfer between optical fields
      Nature Photonics 10, 399–405 (2016). [PDF][Link][Suppl. Info.]
      Nature Photonics Cover [PNG]
      Featured in a "News and Views”: Optomechanics: Vibrations copying optical chaos,
      Nature Photonics 10, 366–368 (2016). [PDF][Link]

    19. Y.L. Liu, R. Wu, J. Zhang, S.K. Ozdemir, L. Yang, F. Nori, Y.X. Liu
      Controllable optical response by modifying the gain and loss of a mechanical resonator and cavity mode in an optomechanical system
      Phys. Rev. A 95, 013843 (2017). [PDF][Link][arXiv]

    20. H. Jing, S.K. Ozdemir, H. Lu, F. Nori
      High-order exceptional points in optomechanics
      Scientific Reports 7, 3386 (2017). [PDF][Link][arXiv]

    21. M. Cirio, K. Debnath, N. Lambert, F. Nori
      Amplified Optomechanical Transduction of Virtual Radiation Pressure
      Phys. Rev. Lett. 119, 053601 (2017). [PDF][Link][arXiv][Suppl. Info.]

    22. V. Macri, A. Ridolfo, O. Di Stefano, A.F. Kockum, F. Nori, S. Savasta
      Nonperturbative Dynamical Casimir Effect in Optomechanical Systems: Vacuum Casimir-Rabi Splittings
      Phys. Rev. X 8, 011031 (2018). [PDF][Link][arXiv]

    23. N. Yang, A. Miranowicz, Y.C. Liu, K. Xia, F. Nori
      Chaotic synchronization of two optical cavity modes in optomechanical systems
      Scientific Reports 9, 15874 (2019). [PDF][Link_1][Link_2][arXiv]

    24. X. Wang, W. Qin, A. Miranowicz, S. Savasta, F. Nori
      Unconventional cavity optomechanics: Nonlinear control of phonons in the acoustic quantum vacuum
      Phys. Rev. A 100, 063827 (2019). [PDF][Link][arXiv]

    25. D.G. Lai, X. Wang, W. Qin, B.P. Hou, F. Nori, J.Q. Liao
      Tunable optomechanically induced transparency by controlling the dark-mode effect
      Phys. Rev. A 102, 023707 (2020). [PDF][Link][arXiv]

    26. X.L. Dong, P.B. Li, T. Liu, F. Nori
      Unconventional Quantum Sound-Matter Interactions in Spin-Optomechanical-Crystal Hybrid Systems
      Phys. Rev. Lett. 126, 203601 (2021). [PDF][Link][arXiv][Suppl. Info.]

    27. S. Hughes, A. Settineri, S. Savasta, F. Nori
      Resonant Raman scattering of single molecules under simultaneous strong cavity coupling and ultrastrong optomechanical coupling in plasmonic resonators: Phonon-dressed polaritons
      Phys. Rev. B 104, 045431 (2021). [PDF][Link][arXiv]

    28. D.G. Lai, W. Qin, B.P. Hou, A. Miranowicz, F. Nori
      Significant enhancement in refrigeration and entanglement in auxiliary-cavity-assisted optomechanical systems
      Phys. Rev. A 104, 043521 (2021). [PDF][Link][arXiv]

    29. H. Xu, D.G. Lai, Y.B. Qian, B.P. Hou, A. Miranowicz, F. Nori
      Optomechanical dynamics in the PT- and broken-PT-symmetric regimes
      Phys. Rev. A 104, 053518 (2021). [PDF][Link][arXiv]

    30. J. Huang, D.G. Lai, C. Liu, J.F. Huang, F. Nori, J.Q. Liao
      Multimode optomechanical cooling via general dark-mode control
      Phys. Rev. A 106, 013526 (2022). [PDF][Link][arXiv]

    31. D.G. Lai, J.Q. Liao, A. Miranowicz, F. Nori
      Noise-Tolerant Optomechanical Entanglement via Synthetic Magnetism
      Phys. Rev. Lett. 129, 063602 (2022). [PDF][Link][arXiv][Suppl. Info.]

    32. D.G. Lai, W. Qin, A. Miranowicz, F. Nori
      Efficient optomechanical refrigeration of two vibrations via an auxiliary feedback loop: Giant enhancement in mechanical susceptibilities and net cooling rates
      Phys. Rev. Research 4, 033102 (2022). [PDF][Link]

    33. D.G. Lai, Y.H. Chen, W. Qin, A. Miranowicz, F. Nori
      Tripartite optomechanical entanglement via optical-dark-mode control
      Phys. Rev. Research 4, 033112 (2022). [PDF][Link]

    34. R. Xu, D.G. Lai, B.P. Hou, A. Miranowicz, F. Nori
      Millionfold improvement in multivibration-feedback optomechanical refrigeration via auxiliary mechanical coupling
      Phys. Rev. A 106, 033509 (2022). [PDF][Link][arXiv]

    35. V. Macri, A. Mercurio, F. Nori, S. Savasta, C.S. Munoz
      Spontaneous scattering of raman photons from cavity-QED systems in the ultrastrong coupling regime
      Phys. Rev. Lett., accepted (2022). [arXiv]