The Quantum Features of Correlated Photons with the Effect of Phase Fluctuation

Authors

  • A.G. Kumela Department of Applied Physics, School of Applied Sciences, Adama Science and Technology University
  • A.B. Gemta Department of Applied Physics, School of Applied Sciences, Adama Science and Technology University
  • A.K. Hordofa Department of Applied Physics, School of Applied Sciences, Adama Science and Technology University
  • T.A. Desta Department of Applied Physics, School of Applied Sciences, Adama Science and Technology University
  • M. Dangish Department of Applied Physics, School of Applied Sciences, Adama Science and Technology University
  • H.D. Mekonnen Department of Applied Physics, School of Applied Sciences, Adama Science and Technology University

DOI:

https://doi.org/10.15407/ujpe68.2.81

Keywords:

quantum features, correlated photons, nondegenerate three-level laser, entanglement

Abstract

We theoretically investigate the effect of phase fluctuations on correlated photons resulting from nondegenerate three-level atoms under the cavity radiation. The photon statistics, photon number correlation, and entanglement properties of the system have been calculated employing the dynamical equation of the system. It is shown that, for the sub-Poissonian photon statistics, the degree of correlation increases with the atomic pumping rate, and the entanglement varies with phase fluctuations, rather than with the atomic pumping rate. The proposed system is well suitable for the quantum information processing.

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Published

2023-04-20

How to Cite

Kumela, A., Gemta, A., Hordofa, A., Desta, T., Dangish, M., & Mekonnen, H. (2023). The Quantum Features of Correlated Photons with the Effect of Phase Fluctuation. Ukrainian Journal of Physics, 68(2), 81. https://doi.org/10.15407/ujpe68.2.81

Issue

Vol. 68 No. 2 (2023)

Section

Optics, atoms and molecules

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