Evolution of the intensity- and time-dependent field quantum entropy of the  field-atom coupled system

Abstract

Abstract: Based on the Von Neumann quantum reduced entropy theory, the evolution properties of field quantum entropy in the interaction system of L-type three-level atom and single-model field are studied when the coupling between the field and the atom changes with time and intensity under the on-resonance condition . The influences of the different initial fields and the changes of the coupling coefficient on the field quantum entropy is discussed in detail through numerical calculation. The results show that the different statistical properties of the initial fields will lead to the great variation of the field quantum entropy, and the changes of the coupling strength modulation function will change the oscillating frequency of the evolution of the field quantum entropy. In addition, it is shown that the initial stage of the interaction between the field and the atom is a gradually coupled procedure, and the superposition state probability of the atom makes the field quantum entropy change periodically.

Key words: quantum optics, evolution of field quantum entropy；intensity-dependent and time-dependent coupling, Von Neumann quantum reduced entropy theory, L-type three-level atom

CLC Number:

O431.2

LIU Wangyun, PAN Congyi, YANG Zhiyong, DUAN Cunli. Evolution of the intensity- and time-dependent field quantum entropy of the field-atom coupled system[J]. Chinese Journal of Quantum Electronics, 2020, 37(2): 215-221.

References

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Evolution of the intensity- and time-dependent field quantum entropy of the field-atom coupled system

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