Coupling enhancement and symmetrization of single-photon optomechanics in open quantum systems

A challenging task of cavity optomechanics is to observe single-photon optomechanical effects. To explore an intrinsic nonlinear effect of single-photon cavity optomechanics, we need to strengthen the radiation-pressure (RP) interaction between a single photon and a finite number of phonons. In this work, introducing the two-laser driving and considering the second-order correction to the cavity resonance frequency beyond the RP interaction, we realize controllable enhancement of the single-photon optomechanical coupling in a prototypical Fabry-Perot cavity. By adjusting the parameters of the two driving lasers and the cross-Kerr (CK) interaction so that the effective optomechanical coupling may become a real number, we theoretically propose effective symmetric optomechanical dynamics at the single-photon level, in which the forms of the quantum fluctuation dynamics satisfied by the photon and phonon are identical to each other. We study optimal reciprocal transport in symmetric optomechanics. By observing the critical behavior of the optimal transmission of the laser field, we identify the boundary point of the optomechanical strong coupling. We compare the scattering behavior of the laser field in the dissipative equilibrium and non-equilibrium symmetric optomechanics before and after the rotating-wave approximation (RWA). We also present a reliable experimental implementation of the present scheme. This work may pave the way to studying the single-photon optomechanical effects with current experimental platforms.
Comment: 19 pages, 13 figures, and 3 tables