在腔量子电动力学模型中引入经典场驱动原子, 通过设置原子-腔场的频率失谐量与经典场驱动强度的关系, 实现有效Jaynes-Cummings模型到反Jaynes-Cummings模型的转化, 从而达到控制系统动力学过程的目的。分别讨论了三原子Greenberger-Horne-Zeilinger (GHZ)型和W型纠缠态在不同原子-腔场有效相互作用模型下的纠缠动力学行为。结果发现, 在经典场驱动下, 三原子纠缠在动力学过程中可以实现从存在纠缠死亡现象到无纠缠死亡现象的转化, 从而抑制纠缠突然死亡现象的发生。探究了泄漏腔情形下三原子GHZ型和W型纠缠态在演化过程中的纠缠稳健性, 得到了三原子GHZ型和W型纠缠态在动力学过程中纠缠稳健性最强的有效原子-腔场相互作用模型。

The atoms are driven by classical field introduced in the cavity quantum electro-dynamic model. By setting the relationship between frequency detuning of atom-cavity field and classical field driven strength, the transformation from the effectively Jaynes-Cummings model to the anti-Jaynes-Cummings model is achieved. The dynamic process of the whole system can be controlled. The entanglement dynamic behaviors of three-atom Greenberger-Horne-Zeilinger (GHZ)-type and W-type entanglement states in different effective atom-cavity field interaction models are discussed. The results show that the three-atom entanglement state in dynamic process can change from entanglement-sudden-death to no-entanglement-sudden-death with the assisting of classical field, so the phenomenon of entanglement-sudden-death can be inhibited. The entanglement robustness of the three-atom GHZ-type and W-type entanglement states in dissipative cavity is explored in the evolutionary process. The effective atom-cavity interaction model of the three-atom GHZ-type and W-type entanglement states are obtained in dynamic process in which the strongest robustness can be acquired.