Effect of linear and nonlinear coupling processes on correlation properties of bosonic modes

TL;DR

This paper investigates how linear and nonlinear coupling processes affect correlation properties of two bosonic modes, revealing distinct mechanisms and effects on correlations, coherence, and mode states under different coupling conditions.

Contribution

It provides a comparative analysis of linear and nonlinear couplings on bosonic modes, highlighting their different roles in generating and destroying correlations and coherence.

Findings

Linear coupling generates correlations only with mode differences.

Nonlinear coupling's correlation generation is insensitive to mode differences.

Strong linear coupling destroys correlations and equalizes mode states.

Abstract

We study the influence of the linear and nonlinear coupling processes on the correlation properties of a system composed of two bosonic modes. The coupling processes are treated as Gaussian while the modes are assumed to experience damping and fluctuations that are due to their coupling to independent squeezed vacua. We investigate under what circumstances a given type of coupling causes the creation of the first-order correlations and which causes the creation of the two-photon correlations. Distinctly different results are obtained for the linear and nonlinear couplings, especially when there are two-photon correlations present in the modes. In particular, the linear coupling process can generate the inter-mode correlations only when there are differences between the modes either in populations or two-photon correlations. The varying with the coupling strength a population difference is shown to be responsible for generation of the first-order correlations while the varying asymmetry in the two-photon correlations is found to be responsible for the generation of the inter-mode two-photon correlations. In the case of the nonlinear coupling the generation of the inter-mode correlations is insensitive to any difference between the modes. The varying with the coupling strength amplification of the population of the modes is found to be responsible for generation of the inter-mode two photon correlations while the varying amplification of the two-photon correlations results in the first-order correlations between the modes. Furthermore, in the strong coupling limit the linear coupling tends to destroy all of the inter-mode correlations, and simultaneously turns the states of the modes to be identical, either thermal or equally squeezed states. In the case of nonlinear coupling process the modes are turned to be perfectly coherent.