Quantum coherence and phase-space nonclassicality in k-photon thermal-noisy nonlinear JCM with atomic motion

Quantum coherence and phase-space nonclassicality in k-photon thermal-noisy nonlinear JCM with atomic motion

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In this paper, we study the quantum interaction between a moving 4 Piece LAF Sectional Sleeper two-level atom and a single-mode quantized field in an optical cavity with degenerate multi-photon transition, in the presence of intensity-dependent coupling and thermal effect.We introduce the appropriate Hamiltonian of the system, and we adopt the initial condition of subsystems, in which the atom is prepared in an arbitrary superposition of ground and excited states, and the field is considered in a thermal state.Consequently, we determine the density matrix of the entire system at any given time.We further assess some of the most important quantum properties, such as quantum coherence, sub-Poissonian statistics, and phase-space nonclassicality by means 90s Jean of negativity of the Wigner quasiprobability distribution function.

We then investigate the impact of intensity-dependent nonlinearity, thermal noise, atomic motion, and multi-photon transition on these quantum properties.The numerical results show that the nonclassicality criteria can be significantly influenced and controlled by the effects discussed above.Interestingly, increasing the mean thermal photon number, which highlights the thermal effect, can, in some cases, enhance the nonclassicality features of the system.