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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. 相似文献
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由于绝热条件几何相位量子逻辑门存在非绝热差错与退相干差错这一冲突,因此在拓扑量子计算中需要设计非绝热条件几何相门,以克服这一不足.证明螺旋光纤系统内光子有效哈密顿量恰好是一个Wang Matsumoto型哈密顿量,因此螺旋光纤系统能自动产生非绝热条件几何相移.同时还证明在螺旋光纤方案中,由极化光子与螺旋光纤相互作用哈密顿量所导致的动力学相位为零(这正是拓扑量子计算所要求的),以及在螺旋光纤系统中可以通过控制极化光子初始波矢,从而较容易获得条件初始态.总之,螺旋光纤系统方案能自动满足Wang与Matsumoto的核磁共振方案中为实现非绝热条件几何相移所提出的全部条件与要求.
关键词:
几何相位
螺旋光纤系统
Wang Matsumoto型哈密顿量
拓扑量子计算 相似文献
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文章首先概述了近年国际文献中关于量子绝热近似和绝热条件的不自洽性的研究.叙述了文献中关于绝热近似不自洽性的论证和争论.然后引入文章作者的观点,从不同于国外文献的角度出发指出应当正确地理解瞬时本征函数的相位问题,从这个相位的正确处理,得出结论:(1)MS不自洽的存在,不因计及几何相位而消除;(2)量子几何相位不自洽是不存在;(3)现时的标准的绝热近似条件不是充分条件. 相似文献
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对于Hamiltonian随时间作周期变化的量子系统中状态的演化,Bloch定理亦成立,并可据此定义一种新的几何相位———Bloch相位.证明用这种新的几何相位可以把迄今发现的所有同步(即量子态演化一周后获得的)几何相位统一起来,即Bloch相位等于Pancharatnam相位、Aharonov-Anandan相位和Lewis-Riesenfeld相位,并且在绝热条件下化为Bery相位.为此,先对Pancharatnam相位、Aharonov-Anandan相位和Lewis-Riesenfeld相位的定义作等价的改变,使它们变得有物理意义,并把Lewis-Riesenfeld相位和Berry相位推广到简并情形.还讨论了Bloch相位的求解问题
关键词: 相似文献
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文章首先概述了近年国际文献中关于量子绝热近似和绝热条件的不自洽性的研究.叙述了文献中关于绝热近似不自洽性的论证和争论.然后引入文章作者的观点,从不同于国外文献的角度出发指出应当正确地理解瞬时本征函数的相位问题,从这个相位的正确处理,得出结论:(1)MS不自洽的存在,不因计及几何相位而消除;(2)量子几何相位不自洽是不存在;(3)现时的标准的绝热近似条件不是充分条件. 相似文献
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针对绝热算法在系统演化过程中需要较长操作时间的问题,本文提出了电路量子电动力学系统中基于超绝热捷径的两量子比特控制相位门的快速制备方案.首先将量子比特的能级进行编码,针对不同初始态分类讨论,获得系统的有效哈密顿量.通过反绝热驱动,推导出系统有效哈密顿量的修正项,以抑制不同本征态之间不必要的跃迁,从而获得了高保真度的基于超绝热捷径控制相位门.数值模拟验证了本方案的有效性,最终保真度为0.991.所提方案可以加速演化,并且比绝热通道更有效.此外,本方案对谐振器的衰减和超导量子比特的退相干具有鲁棒性.通过对谐振腔的泄漏、量子比特的自发辐射和退相位的影响分析,得到的系统最终保真度始终保持在0.984以上. 相似文献
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文章研究了自旋为1的粒子在旋转磁场中的几何相位和动力学相位.推导出如何计算自旋为1的粒子在绝热和非绝热演化中的几何相位和动力学相位公式,并利用这些公式计算其相位.最后我们讨论了三种情况下的Berry相位,当考虑ω1<<ω时,系统处于绝热近似,此时,几何相位就是Berry相位. 相似文献
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研究了双轴各向异性负折射率材料光纤中光传播特性及光子波函数几何相位的特殊性质. 为体现其拓扑与整体效应,光子几何相位必依赖于螺旋光纤中光子波函数演化路径所张开的立体角. 本研究证明,在双轴各向异性负折射率材料光纤中,因在光的传播过程中正负折射率对于光波几何相位的贡献可以相互抵消,因此光子几何相位将与光子波函数演化路径所张锥角无关. 还讨论了源于量子涨落效应的真空水平光子几何相位的物理性质以及在实验上探测这一真空效应的可能性.
关键词:
各向异性
负折射率材料
几何相位
光纤 相似文献
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The adiabatic geometric phase is calculated in a coupled two quantum dot system, which is entangled through Förster interaction. This phase is then utilized for implementing basic quantum logic gate operation useful in quantum information processing. Such gates based on geometric phase provide fault-tolerant quantum computing. 相似文献
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Zheng SB 《Physical review letters》2005,95(8):080502
We propose a new approach to quantum phase gates via the adiabatic evolution. The conditional phase shift is neither of dynamical nor geometric origin. It arises from the adiabatic evolution of the dark state itself. Taking advantage of the adiabatic passage, this kind of quantum logic gates is robust against moderate fluctuations of experimental parameters. In comparison with the geometric phase gates, it is unnecessary to drive the system to undergo a desired cyclic evolution to obtain a desired solid angle. Thus, the procedure is simplified, and the fidelity may be further improved since the errors in obtaining the required solid angle are avoided. We illustrate such a kind of quantum logic gates in the ion trap system. The idea can also be realized in other systems, opening a new perspective for quantum information processing. 相似文献
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Geometric phases are robust to local noises and the nonadiabatic ones can reduce the evolution time, thus nonadiabatic geometric gates have strong robustness and can approach high fidelity. However, the advantage of geometric phase has not been fully explored in previous investigations. Here,a scheme is proposed for universal quantum gates with pure nonadiabatic and noncyclic geometric phases from smooth evolution paths. In the scheme, only geometric phase can be accumulated in a fast way, and thus it not only fully utilizes the local noise resistant property of geometric phase but also reduces the difficulty in experimental realization. Numerical results show that the implemented geometric gates have stronger robustness than dynamical gates and the geometric scheme with cyclic path. Furthermore, it proposes to construct universal quantum gate on superconducting circuits, with the fidelities of single-qubit gate and nontrivial two-qubit gate can achieve 99.97% and 99.87%, respectively. Therefore, these high-fidelity quantum gates are promising for large-scale fault-tolerant quantum computation. 相似文献
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We propose a scheme for realizing a controlled geometric phase gate for twoneutral atoms. We apply the stimulated Raman adiabatic passage to transferatoms from their ground states into Rydberg excited states, and use theRydberg interaction induced energy shifts to generate geometric phase andconstruct quantum gates. 相似文献
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A conditional geometric phase shift gate, which is fault tolerant to certain types of errors due to its geometric nature, was realized recently via nuclear magnetic resonance (NMR) under adiabatic conditions. However, in quantum computation, everything must be completed within the decoherence time. The adiabatic condition makes any fast conditional Berry phase (cyclic adiabatic geometric phase) shift gate impossible. Here we show that by using a newly designed sequence of simple operations with an additional vertical magnetic field, the conditional geometric phase shift gate can be run nonadiabatically. Therefore geometric quantum computation can be done at the same rate as usual quantum computation. 相似文献
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The possibility of realization of quantum gates by means of the nonadiabatic geometric phase is considered. It is shown that the nonadiabatic phase can be used for realization of quantum gates as successfully as the adiabatic phase. 相似文献
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Quantum gates, which are the essential building blocks of quantum computers, are very fragile. Thus, to realize robust quantum gates with high fidelity is the ultimate goal of quantum manipulation. Here, we propose a nonadiabatic geometric quantum computation scheme on superconducting circuits to engineer arbitrary quantum gates, which share both the robust merit of geometric phases and the capacity to combine with optimal control technique to further enhance the gate robustness. Specifically, in our proposal, arbitrary geometric single-qubit gates can be realized on a transmon qubit, by a resonant microwave field driving, with both the amplitude and phase of the driving being timedependent. Meanwhile, nontrivial two-qubit geometric gates can be implemented by two capacitively coupled transmon qubits, with one of the transmon qubits’ frequency being modulated to obtain effective resonant coupling between them. Therefore, our scheme provides a promising step towards fault-tolerant solid-state quantum computation. 相似文献
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We propose a new class of unconventional geometric gates involving nonzero dynamic phases, and elucidate that geometric quantum computation can be implemented by using these gates. Comparing with the conventional geometric gate operation, in which the dynamic phase shift must be removed or avoided, the gates proposed here may be operated more simply. We illustrate in detail that unconventional nontrivial two-qubit geometric gates with built-in fault-tolerant geometric features can be implemented in real physical systems. 相似文献
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Lin Xu Gang Huang Y. H. Ji Z. S. Wang 《International Journal of Theoretical Physics》2010,49(9):2002-2015
Implements for geometric quantum gates are analyzed in the electric circuit. We find that, by operating the difference of
geometric phase between eigenstates of Hamiltonian for single-particle system and two-particle system respectively, one may
perfectly preserve the messages for single-particle gate as well as entangling geometric two-particle gate. 相似文献