量子混合态的统计角

本文把关于量子纯态之间的统计角概念推广到量子混合态,并提出了单个混合态的发散角这一概念,导出了纯态判据,用到测量上,响应函数不过是量子系统与仪器之间的统计角余弦的平方,而测量过程中的熵增加则显现为混合态发散角的扩大。 关键词：     

混合态二能级原子双光子过程的量子特性

采用时间演化算符方法研究了相干光场与混合二能级以光了过程的粒子数反转和光子演化行为，结果表明：量子崩塌与复苏性质和原子实始的混合程度无关，但振荡最大幅值受原子初始混合程度的支配，随着原子初始混合程度的增大，原子反转几率减小，〈ｎ〉的时间平均值下降。     

压缩真空态中三能级原子的定态共振荧光

本文得到了与压缩白噪声真空库耦合的三能级原子在强相干驱动场作用下的定态共振荧光谱。结果表明谱分布强烈地依赖于库场压缩性及相干驱动场与库场压缩分量之间的位相差。 关键词：     

量子体系演化的几何相位

量子体系在演化过程中,其状态的时间演化因子除众所周知的由系统能谱决定的动力学相位因子外,还会出现与系统演化路径有关的几何相位因子即Berry相位因子。几何相位的存在已为大量实验所证实,在理论上,已确定了其数学基础是纤维丛理论,并发现它与规范场有某些联系。本文评述了有关几何相位研究工作的进展。     

量子相变与几何相位

量子相变是凝聚态物理中的重要研究课题,而几何相位的发现是近几十年来量子力学中的重要进展,它们毫无关联地各自发展.但最近的研究表明,它们之间有密切联系：多体体系基态的几何相位在量子相变点附近具有标度性;不可收缩的几何相位可用来作为量子相变的标志等.文章将介绍最近在量子相变和几何相位的关系方面的研究进展,并用XY自旋链模型来详细说明.这些结果应会吸引凝聚态和几何相位领域工作的研究人员的关注和兴趣.     

Λ型三能级原子与两个谐振器的量子相位门

量子纠缠的生成和操控在量子通信和量子信息处理中具有广泛的应用价值.通过构建单个Λ型三能级原子和两个超导谐振器之间相互耦合的模型,给出了实现控制Z门(Controlled-Z)的四种操作方案和实现交换门(Swap)的两种操作方案;同时对实现控制Z门的第一种操作方案进行了保真度的数值模拟仿真.结果表明:通过20.83 ns的运行时间,其保真度为96.67%,而衰减率、弛豫速率和移相比率的增加会降低系统的保真度,而耦合强度的增加会减少系统的运行时间,从而减小衰减参数的影响,提高系统的保真度.     

量子力学混合态表象

在以往的文献中量子力学的表象都是纯态表象,在本文中我们从算符的合理排序和概率统计的正态分布思想出发,首次提出了量子力学混合态表象的概念,并证明了其完备性和正交性.量子力学混合态表象的优点是可以反映算符的多种表示以及其相应的排序规则.     

关于Lewis-Riesenfeld相位和量子几何相位

评注了《大学物理》21 23一文关于量子几何相位与Lewis相位论述与《物理学报》48 2018一文的结论有极大不同.指出前者对Lewis导出的相位与量子几何相位关系的错误陈述，而后者的结论是正确的. 关键词： 量子几何相位 不变量方法 Lewis-Riesenfeld相位     

光泵三能级原子体系产生光子数压缩态

本文证明光泵三能级原子体系可以产生光子数压缩态。分别计算非相干泵浦、弱相干泵浦和强相于泵浦几种情形下的Fano因数。结果表明,弱相干泵浦时可获得最佳压缩效应,相应的Fano因数为0.16。这种产生光子数压缩态的方法在实验上是简便可行的。 关键词：     

具有三体相互作用的自旋链系统中的几何相位与量子相变

本文首先对具有三体相互作用的一维自旋链系统的哈密顿量进行了对角化．然后通过一个旋转操作求解了系统基态的几何相位,通过数值计算几何相位及其导数随外界参数的变化,考虑三体相互作用对几何相位以及量子相变的影响,结果表明几何相位可以很好的用来表征该系统中的量子相变,并且发现三体相互作用不但引起相变点平移,而且可以产生新的临界点．     

Geometric Phases for Mixed States in Trapped Ions

The generalization of geometric phase from the pure states to the mixed states may have potential applications in constructing geometric quantum gates. We here investigate the mixed state geometric phases and visibilities of the trapped ion system in both non-degenerate and degenerate cases. In the proposed quantum system, the geometric phases are determined by the evolution time, the initial states of trapped ions, and the initial states of photons. Moreover,special periods are gained under which the geometric phases do not change with the initial states changing of photon parts in both non-degenerate and degenerate cases. The high detection efficiency in the ion trap system implies that the mixed state geometric phases proposed here can be easily tested.     

Geometric Phases for Mixed States in Trapped Ions

The generalization of geometric phase from the pure states to the mixed states may have potential applications in constructing geometric quantum gates. We here investigate the mixed state geometric phases and visibilities of the trapped ion system in both non-degenerate and degenerate cases. In the proposed quantum system, the geometric phases are determined by the evolution time, the initial states of trapped ions, and the initial states of photons. Moreover, special periods are gained under which the geometric phases do not change with the initial states changing of photon parts in both non-degenerate and degenerate cases. The high detection efficiency in the ion trap system implies that the mixed state geometric phases proposed here can be easily tested.     

Geometric phase under the Unruh effect with intermediate statistics

Utilizing the geometric phase (GP) acquired in a quantum evolution, we manifest the thermality and quantum nature of the Unruh effect of an accelerating detector. We consider an UDW detector coupling to a conformal field in Minkowski spacetime, whose response spectrum exhibits an intermediate statistics of (1+1) anyon field. We find that comparing to an inertial moving detector, the GP in accelerating frame is modified after the nonunitary evolution of the detector due to the Unruh effect. We show that such modification can distinguish the different thermalizing ways of the detector, which depends on the scaling dimension of the conformal primary field. Finally, we estimate the difference between the GP under the Unruh radiation and that in a thermal bath for a static observer, which reveals the quantum origin of the Unruh effect rather than a conventional thermal noise.     

几何量子计算

实现可集成的量子计算的关键步骤是实现保真度足够高的一组普适量子逻辑门，最近几年发展的几何量子计算使用几何位相来实现量子逻辑门，其特点是利用几何位相的整体几何性质来避免某些局域的无规噪声的影响，从而实现较高保真度的量子门，文章先简要介绍常规几何量子逻辑门的概念，然后重点介绍最近提出的非常规几何量子计算：量子计算中使用的逻辑门的总位相既包含有几何位相，又包含有动力学位相，但它仅依赖于一些几何特征，而且，对于任意的量子位输入态，在量子门操作过程中积累的位相要么是零，要么是仅依赖几何特征的位相。     

绝热演化中一般量子态的几何相位

在绝热演化中的几何相位（即Berry相位）被推广到包括非本征态的一般量子态.这个新的几何相位同时适用于线性量子系统和非线性量子系统.它对于后者尤其重要因为非线性量子系统的绝热演化不能通过本征态的线性叠加来描述.在线性量子系统中,新定义的几何相位是各个本征态Berry相位的权重平均.     

JC模型体系的几何相

利用AA相理论,给出了Jaynes-cummings模型系统在初始状态为固定光子数下的几何相.     

Geometric phase of an open double-quantum-dot system detected by a quantum point contact

We study theoretically the geometric phase of a double-quantum-dot(DQD) system measured by a quantum point contact(QPC) in the pure dephasing and dissipative environments, respectively. The results show that in these two environments, the coupling strength between the quantum dots has an enhanced impact on the geometric phase during a quasiperiod. This is due to the fact that the expansion of the width of the tunneling channel connecting the two quantum dots accelerates the oscillations of the electron between the quantum dots and makes the length of the evolution path longer.In addition, there is a notable near-zero region in the geometric phase because the stronger coupling between the system and the QPC freezes the electron in one quantum dot and the solid angle enclosed by the evolution path is approximately zero,which is associated with the quantum Zeno effect. For the pure dephasing environment, the geometric phase is suppressed as the dephasing rate increases which is caused only by the phase damping of the system. In the dissipative environment,the geometric phase is reduced with the increase of the relaxation rate which results from both the energy dissipation and phase damping of the system. Our results are helpful for using the geometric phase to construct the fault-tolerant quantum devices based on quantum dot systems in quantum information.     

Geometric quantum discord and Berry phase between two charge qubits coupled by a quantum transmission line

Geometric quantum discord（GQD） and Berry phase between two charge qubits coupled by a quantum transmission line are investigated. We show how GQDs evolve and investigate their dependencies on the parameters of the system.We also calculate the energy and the Berry phase and compare them with GQD, finding that there are close connections between them.