共查询到19条相似文献,搜索用时 156 毫秒
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量子信息讲座 第三讲 量子编码 总被引:3,自引:0,他引:3
量子编码使信息论领域发生革命性进展,它是量子信息论的主要内容之一。文章介绍了量子编码的基本概念和发展背景,评述一些现有的量子编码方案,包括纠随机错和防合作错的量子码,并追踪量子编码定理的研究进展。 相似文献
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量子信息掩蔽是量子信息处理中的一个新兴概念,它将量子信息完全转移至各个量子实体的关联之中,从而使单个量子系统不再包含掩蔽前的任何信息。量子信息掩蔽在量子比特承诺、秘密共享等方面都具有重要的应用;然而与量子态的克隆、广播、隐藏等操作类似,人们无法使用一个普适的两体幺正演化来实现量子信息的掩蔽。本文系统地介绍近期量子信息掩蔽方向的一系列研究进展:首先描述了可实现量子信息掩蔽态集合的几何特征,给出掩蔽操作的实现方法,讨论了其在信息论中的含义以及与量子纠错码等概念的联系;然后介绍量子信息掩蔽的实验实现,展现量子信息掩蔽在高维体系等复杂系统中的可行性,并展示其在量子秘密共享和噪声免疫的量子通信等方面的应用。 相似文献
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量子信息讲座续讲
第二讲 量子信息安全系统 总被引:2,自引:0,他引:2
详细介绍了量子密码的相关内容,包括量子密码理论基础、量子保密系统、量子认证系统、量子密码与其他学科的关系以及量子密码的应用与展望,并追踪了量子信息安全系统的最新研究进展. 相似文献
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详细介绍了量子密码的相关内容,包括量子密码理论基础、最子保密系统、量子认证系统、量子密码与其他学科的关系以及量子密码的应用与展望,并追踪了量子信息安全系统的最新研究进展。 相似文献
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过去的二十年中,量子信息相关研究取得了显著的进展,重要的理论和实验工作不断涌现.与其他量子信息处理系统相比,基于自旋动力学的核磁共振系统,不仅具有丰富而且成熟的控制技术,还拥有相干时间长、脉冲操控精确、保真度高等优点.这也是核磁共振体量子系统能够精确操控多达12比特的量子系统的原因.因此,核磁共振量子处理器在量子信息领域一直扮演着重要角色.本文介绍核磁共振量子计算的基本原理和一些新研究进展.研究的新进展主要包括量子噪声注入技术、量子机器学习在核磁共振平台上的实验演示、高能物理和拓扑序的量子模拟以及核磁共振量子云平台等.最后讨论了液态核磁共振的发展前景和发展瓶颈,并对未来发展方向提出展望. 相似文献
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A gauge-invariant Green’s function approach to the quantum transport of spatially confined electrons in strong electromagnetic fields is presented. The theory includes mean field and exchange effects, as well as collisions and initial correlations. It allows for a self-consistent treatment of spectral properties and collective effects (plasmons), on one hand, and nonlinear field phenomena, such as harmonic generation and multiphoton absorption, on the other. It is equally applicable to electrons in quantum dots, ultracold ions in traps and valence electrons of metal clusters. 相似文献
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《Physics letters. A》2020,384(23):126447
Quantum correlations in an entangled many-body system are capable of storing information. Even when the information is injected by a local unitary operation to the system, the entanglement delocalizes it. In a recent study on multiple-qubit systems, it is shown that a virtual qubit defined in the correlation space plays a role of perfect storage of delocalized information, which is called a quantum information capsule (QIC). To enhance the capacity of quantum information storage, it is crucial to formulate the cases for multiple-qudit systems and continuous-variable (CV) systems. We analytically prove that it is possible to construct a QIC for general write operations of the systems. It turns out that the extension to quantum field theory is achievable. For Gaussian states, we explicitly construct a QIC for shift write operations. We analyze the time-evolution of QIC in a CV system to demonstrate the diffusion of information in entangled pure states. 相似文献
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It is well known that loss of information about a system, for some observer, leads to an increase in entropy as perceived by this observer. We use this to propose an alternative approach to decoherence in quantum field theory in which the machinery of renormalisation can systematically be implemented: neglecting observationally inaccessible correlators will give rise to an increase in entropy of the system. As an example we calculate the entropy of a general Gaussian state and, assuming the observer's ability to probe this information experimentally, we also calculate the correction to the Gaussian entropy for two specific non-Gaussian states. 相似文献
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Karen A. Hallberg 《物理学进展》2013,62(5-6):477-526
The density matrix renormalization group (DMRG) has become a powerful numerical method that can be applied to low-dimensional strongly correlated fermionic and bosonic systems. It allows for a very precise calculation of static, dynamic and thermodynamic properties. Its field of applicability has now extended beyond condensed matter, and is successfully used in quantum chemistry, statistical mechanics, quantum information theory, and nuclear and high-energy physics as well. In this article, we briefly review the main aspects of the method and present some of the most relevant applications so as to give an overview of the scope and possibilities of DMRG. We focus on the most important extensions of the method such as the calculation of dynamical properties, the application to classical systems, finite-temperature simulations, phonons and disorder, field theory, time-dependent properties and the ab initio calculation of electronic states in molecules. The recent quantum information interpretation, the development of highly accurate time-dependent algorithms and the possibility of using the DMRG as the impurity-solver of the dynamical mean field method (DMFT) give new insights into its present and potential uses. We review the numerous very recent applications of these techniques where the DMRG has shown to be one of the most reliable and versatile methods in modern computational physics. 相似文献
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Quantum cellular automata, which describe the discrete and exactly causal unitary evolution of a lattice of quantum systems, have been recently considered as a fundamental approach to quantum field theory and a linear automaton for the Dirac equation in one dimension has been derived. In the linear case a quantum cellular automaton is isomorphic to a quantum walk and its evolution is conveniently formulated in terms of transition matrices. The semigroup structure of the matrices leads to a new kind of discrete path-integral, different from the well known Feynman checkerboard one, that is solved analytically in terms of Jacobi polynomials of the arbitrary mass parameter. 相似文献
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Jun-Mao Ma Zhi-Yong Jiao Ning Li 《International Journal of Theoretical Physics》2007,46(10):2550-2559
The properties of quantum entanglement in the two-photon Tavis–Cummings model with a Kerr nonlinearity are studied in terms
of quantum information entropy theory. The reduced quantum entropy is employed to investigate the quantum entanglement between
two two-level atoms and a single-mode coherent field. The relative quantum entropy is employed to investigate the quantum
entanglement between the two two-level atoms. The influences of the nonlinear interaction of the Kerr medium with the field
and the atomic dipole-dipole interaction on the properties of quantum entanglement of the system are also examined. Some important
results are obtained. 相似文献
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Sai Vinjanampathy 《Contemporary Physics》2016,57(4):545-579
Quantum thermodynamics is an emerging research field aiming to extend standard thermodynamics and non-equilibrium statistical physics to ensembles of sizes well below the thermodynamic limit, in non-equilibrium situations and with the full inclusion of quantum effects. Fuelled by experimental advances and the potential of future nanoscale applications, this research effort is pursued by scientists with different backgrounds, including statistical physics, many-body theory, mesoscopic physics and quantum information theory, who bring various tools and methods to the field. A multitude of theoretical questions are being addressed ranging from issues of thermalisation of quantum systems and various definitions of ‘work’ to the efficiency and power of quantum engines. This overview provides a perspective on a selection of these current trends accessible to postgraduate students and researchers alike. 相似文献
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M. Manninen M. Koskinen S.M. Reimann B. Mottelson 《The European Physical Journal D - Atomic, Molecular, Optical and Plasma Physics》2001,16(1):381-385
Exact many-body methods as well as current-spin-density functional theory are used to study the magnetism and electron localization
in two-dimensional quantum dots and quasi-one-dimensional quantum rings. Predictions of broken-symmetry solutions within the
density functional model are confirmed by exact configuration interaction (CI) calculations: In a quantum ring the electrons
localize to form an antiferromagnetic chain which can be described with a simple model Hamiltonian. In a quantum dot the magnetic
field localizes the electrons as predicted with the density functional approach.
Received 5 December 2000 相似文献
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The optical Stark effect in semiconductor quantum wires 总被引:1,自引:0,他引:1
A new approach for controlling the optical emission wavelength of semiconductor quantum wires is proposed. The wavelength control resides upon the effect of an intense, long-wavelength laser field radiation applied to the semiconductor structure. Under such condition a strong optical Stark effect leads to optical tunability. Calculation of the optical Stark effect was carried out in the frame of the nonperturbative theory and finite difference method. Different geometries concerning the size of GaAs–AlGaAs quantum wires as well as the polarization direction and the strength of the applied laser field with respect to the quantum structure were considered. 相似文献