Abstract
We propose a scheme for generating an entangled state for two atoms trapped in two separate cavities coupled to each other. The scheme is based on the competition between the unitary dynamics induced by the classical fields and the collective decays induced by the dissipation of two non-local bosonic modes. In this scheme, only one qubit is driven by external classical fields, whereas the other need not be manipulated via classical driving. This is meaningful for experimental implementation between separate nodes of a quantum network. The steady entanglement can be obtained regardless of the initial state, and the robustness of the scheme against parameter fluctuations is numerically demonstrated. We also give an analytical derivation of the stationary fidelity to enable a discussion of the validity of this regime. Furthermore, based on the dissipative entanglement preparation scheme, we construct a quantum state transfer setup with multiple nodes as a practical application.
Highlights
Quantum entanglement is an intriguing property of composite systems
Several interesting schemes concerning the manipulation of quantum states with dissipation dynamics exist, such as the dissipation-induced geometric phase[43], stimulated Raman adiabatic passage (STIRAP) via dissipative quantum dynamics[44], and dissipation-assisted quantum state manipulation in cavities[45]
We propose a scheme for preparing and stabilizing a maximally entangled state in coupled cavities by effectively utilizing the unitary dynamics provided by microwave fields and the dissipation originating from cavity decay, where only one atom is driven by two classical fields with precisely chosen frequencies
Summary
Quantum entanglement is an intriguing property of composite systems. The term refers to inseparable correlations that are stronger than all classical counterparts[1,2]. We propose a scheme for preparing and stabilizing a maximally entangled state in coupled cavities by effectively utilizing the unitary dynamics provided by microwave fields and the dissipation originating from cavity decay, where only one atom is driven by two classical fields with precisely chosen frequencies.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
