Ke-Xia Jiang scite author profile

Bounds of the minimum evolution time between two distinguishable states of a system can help to assess the maximal speed of quantum computers and communication channels. We study the quantum speed limit time of a composite quantum states in the presence of nondissipative decoherence. For the initial states with maximally mixed marginals, we obtain the exactly expressions of quantum speed limit time which mainly depend on the parameters of the initial states and the decoherence channels. Furthermore, by calculating quantum speed limit time for the time-dependent states started from a class of initial states, we discover that the quantum speed limit time gradually decreases in time, and the decay rate of the quantum speed limit time would show a sudden change at a certain critical time. Interestingly, at the same critical time, the composite system dynamics would exhibit a sudden transition from classical to quantum decoherence.

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Improved Landauer's principle and generalized second law of thermodynamics with initial correlations and non-equilibrium surrounding environments

Jiang¹,

Li²,

Fan³

2018

Preprint

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Traditional form of the second law of thermodynamics is strongly restricted by three conditions: One is the initial joint state of the system and surroundings should be a product state, so that there exists no initial correlations. The second is the initial states of surroundings are in equilibrium thermodynamics. And the end is weak couplings between the system and surroundings. This formulation of the second law should be reexamined in order to understand the relations of thermodynamics and information theory, especially, when existing initial correlations. In this work, using the techniques of quantum statistical mechanics for thermodynamics and quantum information science, we recast fundamental laws of thermodynamics from theoretical information point of view. Initial correlations between the system and surroundings are considered, which evolves thermodynamically and result in modifications of the traditional formulations. We obtained improved forms of the entropy increase, Landauer's principle, and the second law of thermodynamics, which are exhibited as equalities rather than inequalities, and through which physical nature of information can be demonstrated precisely. Further, using the language totally belongs to quantum information theory, we give the direction of natural evolution process a new statement: the evolution of an isolated quantum system, where no correlations exist between subsystems, initially, always towards to directions of the correlation information never be decreased. Such result indicates that the traditional principle of entropy increase can be redescribed using information theory, identically.

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The role of the non-Gaussianity plays in the enhancement of the fidelity in continuous variable quantum teleportation

Jiang¹

2013

Optics Communications

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We investigated the role of non-Gaussianity (nG) plays in the enhancement of the fidelity in continuous-variable quantum teleportation of ideal Braunstein and Kimble (BK) protocol for coherent states, theoretically. The de-Gaussification procedure is realized through subtracting photons on the two-mode squeezed vacuum state (TMSVs). We find that the high fidelity always refers to a symmetrical arrangement of photon subtractions on the different modes of the TMSVs. The non-Gaussian resources demonstrate commendable superiorities compare with the Gaussian resources only for symmetrical arrangements of photon subtractions, however, the asymmetrical arrangements do not. When the total number of photon subtractions be a constant, we find that the optimal nG procedure prefers the most asymmetrical arrangement of subtractions. This characteristic is not consistent with the result that the highest fidelity refers to a symmetrical case. Under the same squeezing parameter, a higher nG might not always lead to a higher fidelity.

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Suppressing correlated noise in signals transmitted over the Gaussian memory channels using a2N-port splitter and phase flips

et al. 2014

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A scheme for suppressing the correlated noise in signals transmitted over the bosonic Gaussian memory channels is proposed. This is a compromise solution rather than removing the noise completely. The scheme is based on linear optical elements, two N -port splitters and N number of phase flips. The proposed scheme has the advantages that the correlated noise of the memory channels are greatly suppressed, and the input signal states can be protected excellently when transmitting over the noise channels. We examine the suppressing efficiency of the scheme for the correlated noise, both from quantum information of the states directly transmitted through the noise channel and also from the entanglement teleportation. The operation of phase flips in our scheme is important for the suppression of the correlated noise, which can diminish the effect of noise in quantum communication. Increasing the number of beam splitters also can improve the suppressing efficiency of the scheme in quantum communication.

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Quantum speed limits for Bell-diagonal states

Zhang¹,

Wang²,

Xia³

et al. 2014

Preprint

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Ke-Xia Jiang

Quantum speed limits for Bell-diagonal states

Improved Landauer's principle and generalized second law of thermodynamics with initial correlations and non-equilibrium surrounding environments

The role of the non-Gaussianity plays in the enhancement of the fidelity in continuous variable quantum teleportation

Suppressing correlated noise in signals transmitted over the Gaussian memory channels using a2N-port splitter and phase flips

Quantum speed limits for Bell-diagonal states

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