Abstract
We propose a scheme to show that the system consisting of two macroscopic oscillators separated in space which are coupled through Coulomb interaction displays the classical-to-quantum transition behavior under the action of optomechanical coupling interaction. Once the optomechanical coupling interaction disappears, the entanglement between the two separated oscillators disappears accordingly and the system will return to classical world even though there exists sufficiently strong Coulomb coupling between the oscillators. In addition, resorting to the squeezing of the cavity field generated by an optical parametric amplifier inside the cavity, we discuss the effect of squeezed light driving on this classical-to-quantum transition behavior instead of injecting the squeezed field directly. The results of numerical simulation show that the present scheme is feasible and practical and has stronger robustness against the environment temperature compared with previous schemes in current experimentally feasible regimes. The scheme might possibly help us to further clarify and grasp the classical-quantum boundary.
Highlights
Quantum entanglement[1, 2], a most remarkable feature and a cornerstone of quantum physics, plays a significant role in the foundation of quantum theory and has potential applications in quantum technology, such as quantum information science[3] and quantum metrology[4]
We propose a scheme to show that the system consisting of two macroscopic oscillators separated in space which are coupled through Coulomb interaction displays the classical-to-quantum transition behavior under the auxiliary of the optomechanical coupling interaction
Our investigation indicates that once the optomechanical coupling interaction disappears, the entanglement between the two separated oscillators disappears and the system will return to classical world even though there exists sufficiently strong Coulomb coupling between the oscillators
Summary
Quantum entanglement[1, 2], a most remarkable feature and a cornerstone of quantum physics, plays a significant role in the foundation of quantum theory and has potential applications in quantum technology, such as quantum information science[3] and quantum metrology[4].
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