Effect of thermal noise on the nonclassicality of SU(1,1) and SU(2) coherent states

The effects of thermal noise on quantum systems are often unavoidable at finite temperatures and should be taken into account, in order to get consistent results with experimental data. By focusing on the quantum states of light, this effect has been less considered, particulary in the context of generalized coherent states. So, in this paper, we aim to define quantum states which are generated by SU(1, 1) and SU(2) coherent states in the presence of the thermal noise. Indeed, we introduce the quantum states of light which are composed of thermal states and SU(1, 1) (or SU(2)) coherent states. In other words, we establish a connection between displaced thermal states and the SU(1, 1) and SU(2) Lie groups. Afterward, the nonclassicality of the obtained states is examined to understand the role of thermal noise in physical properties such as sub-Poissonian statistics, quadrature squeezing and Wigner-Weyl quasi-probability distribution function. This goal is achieved by changing the temperature of thermal equilibrium. Interestingly, the numerical results indicate that the nonclassicality of the system can be improved by considering the thermal noise.

Automated summary

The paper focuses on the effects of thermal noise on quantum systems, particularly on the quantum states of light, establishing a connection between thermal states and coherent states. The study indicates that considering thermal noise can improve the nonclassicality of the system.