When one's life quality and living environment go far from his spiritual and material goal that he always pursues, the most real thought is to seek and acquire disentanglement. 当一个人的生活质量,环境和自身追崇的精神和物质理念先去甚远的时候,最真实的想法就是希望得到解脱。
Disentanglement refers to the transformation of entangled quantum system intodisentangled system via some physical processes. 所谓消纠缠,是指通过一定的物理过程,使原来纠缠的量子系统变得“不纠缠”。
The results indicate that the atoms 'state is a pure state which is different from its initial state, and the disentanglement between atoms and field arises provided that the atoms are trapped coherently. 结果表明:相干捕获后的原子态为一不同于初态的纯态,原子系统与光场的纠缠分解。
Disentanglement agent compounded by ourselves is used, the content of UHMWPE> PP and disentanglement agent influencing on mechanical properties, rheological properties and thermal properties are researched. 在体系中加入自行配制地解缠剂Jc-3,研究了UHMWPE、PP和解缠剂的含量对体系力学性能、流动性能和热学性能的影响。
By manipulating the atom outside the field, we can say that entropy evolution of the atom inside the field interacting with light field appears entanglement and disentanglement. 通过操纵腔外的一个原子,原子与光场的演化可以出现纠缠和解纠缠等情况。
The finite-time disentanglement, which is also termed as entanglement sudden death ( ESD), refer to the entanglement of a composite system can decay to zero in a finite time, exhibiting clear difference to the exponential decay of the coherence of a single quantum system. 有限时间解纠缠也被称为纠缠猝死(Entanglementsuddendeath),是指复合体系的纠缠可以在有限时间内退化为零,明显不同于单量子系统相干性随时间的指数型衰减。
The main results of this thesis are as follows. 1. We studied the conditions of atomic finite-time disentanglement in cavity QED. 本文主要内容包括以下几个方面:1.研究了腔量子电动力学(QED)背景中原子有限时间解纠缠发生的条件。
Thus in this thesis, we will made a detailed introduction of our method& perturbation based on unitary transformation, and apply it to several models to investigate the Non-Markovian decoherence and disentanglement dynamics of dissipation two-state system. 本文中,我们介绍一种新的解析方法-基于幺正变换下的微扰理论,并且把此理论应用到具体的实验模型中,推导了耗散二能级系统非马尔可夫退相干和退纠缠动力学。
And detuning, Kerr effect, et al. play an important role for the properties of the quantum entanglement between the atom and the field ( such as evolution period, the degree of entanglement, disentanglement et al.). 另外,失谐量、克尔效应、光场的强度等因素对光场与原子之间的量子纠缠动力学的性质(诸如演化周期、纠缠强度、退纠缠等)有重要的影响。