Etude de tests du caractère quantique de systèmes de dimension supérieur à deux dans des conditions réalistes / Study of access of quantum features of high dimensional systems under realistic conditions

Sohbi, Adel

15 December 2016

Le sujet de cette thèse est une étude de tests du caractère quantique des systèmes de dimension supérieure à deux dans des conditions réalistes. La non-localité est une des propriétés quantiques utile pour des protocoles du domaine des communications quantiques. L’étude réalisée sur les effets de la décohérence (modèles de conditions réalistes) permet de rendre compte des moyens à mettre en oeuvre afin d’optimiser la conservation de la non-localité en pratique. La contextualité est une autre propriété quantique fondamentale avec un potentiel dans le domaine de traitement d’information quantique. Un test de contextualité a été développé pour toutes les dimensions de systèmes quantiques supérieures à deux. Une expérience prenant en compte les enjeux expérimentaux des tests de contextualité est aussi proposée. / The subject of this thesis is a study of tests of the quantum features of systems of dimension greater than two under realistic conditions. Non-locality is one of the quantum properties used in protocols in the field of quantum communications. The study on the effects of the decoherence (models ofrealistic conditions) address the issue of the conservation of non-locality in practice. Contextuality is another fundamental quantum property with a potential power in quantum information processing. A contextuality test has been developed for all dimensions of quantum systems greater than two. An experiment that considers the experimental issues of contextuality tests is also proposed.

Information quantique

Non-localité

Contextualité

Décohérence

Multipartite

Quantum Information

Non-locality

Contextuality

Decoherence

Multipartite

A NEW ALGORITHM FOR THE TIME EVOLUTION OF QUANTUM TRAJECTORY SIMULATIONS AND PHYSICALLY MOTIVATED ERROR MODELS IN 1D QUANTUM CELLULAR AUTOMATA

McNally, Douglas M., II

11 August 2014

No description available.

Physics

Quantum Physics

Quantum Stable Process

HUANG, SHIH TING

January 2015

It is believed that in the long time limit, the limiting behavior of the discrete-time quantum random walk will cross from quantum to classical if we take into account of the decoherence. The computer simulation has already shown that for the discrete-time one-dimensional Hadamard quantum random walk with coin decoherence such that the measurement operators on the coin space are defined by A0 = Ic √1 − p, A1 = |R > < R| √p and A2 = |L > < L > < L| √p is diffusive when 0 < p ≤ 1 and it is ballistic when P = 0. In this thesis, we are going to let p to be dynamical depending on the step t, that is, we consider p = 1/tß, ß ≥ 0 and we found that it has sub-ballistic behavior for 0 < ß < 1. Furthermore, we study not only the coin decoherence, but the total decoherence, that means the measurement operators apply on the Hilbert space H = Hp ⊗ Hc instead of the coin space only. We find that the results are both sub-ballistic for the coin and total decoherence when 0 < ß < 1. Moreover, according to the model given in [T. A. Brun, H. A. Carteret, and A. Ambainis, Phys. Rev. A 67, 032304 (2003)], we know that if the walker has chance to hop to the second nearest neighbor lattice in one step, the long-time behavior is also sub-ballistic and it is similar to that the walker can hop to the third nearest neighbor lattice in one step. By the way, we also find that if we combine the classical part of the model given in [Jing Zhao and Peiqing Tong. One-dimensional quantum walks subject to next nearest neighbor hopping decoherence, Nanjing Normal University, preprint (2014)] with different step length, then this decoherence will also cross from quantum to classical. Finally, we define the quantum γ-stable walk and obtain the quantum γ-stable law with decoherence. By this decoherence, we can see that the limiting behavior of the quantum stable walk will also cross from quantum to classical and we shows that it spreads out faster than the classical stable walk. / Mathematics

Mathematics

Decoherence

Quantum Stable Walk

Quantum Walk

Stable Law

Sub-ballistic

Thermodynamic Based Framework for Determining Sustainable Electric Infrastructures as well as Modeling of Decoherence in Quantum Composite Systems

Cano-Andrade, Sergio

11 March 2014

In this dissertation, applications of thermodynamics at the macroscopic and quantum levels of description are developed. Within the macroscopic level, an upper-level Sustainability Assessment Framework (SAF) is proposed for evaluating the sustainable and resilient synthesis/design and operation of sets of small renewable and non-renewable energy production technologies coupled to power production transmission and distribution networks via microgrids. The upper-level SAF is developed in accord with the four pillars of sustainability, i.e., economic, environmental, technical and social. A superstructure of energy producers with a fixed transmission network initially available is synthesized based on the day with the highest energy demand of the year, resulting in an optimum synthesis, design, and off-design network configuration. The optimization is developed in a quasi-stationary manner with an hourly basis, including partial-load behavior for the producers. Since sustainability indices are typically not expressed in the same units, multicriteria decision making methods are employed to obtain a composite sustainability index. Within the quantum level of description, steepest-entropy-ascent quantum thermodynamics (SEA-QT) is used to model the phenomenon of decoherence. The two smallest microscopic composite systems encountered in Nature are studied. The first of these is composed of two two-level-type particles, while the second one is composed of a two-level-type particle and an electromagnetic field. Starting from a non-equilibrium state of the composite and for each of the two different composite systems, the time evolution of the state of the composite as well as that of the reduced and locally-perceived states of the constituents are traced along their relaxation towards stable equilibrium at constant system energy. The modeling shows how the initial entanglement and coherence between constituents are reduced during the relaxation towards a state of stable equilibrium. When the constituents are non-interacting, the initial coherence is lost once stable equilibrium is reached. When they are interacting, the coherence in the final stable equilibrium state is only that due to the interaction. For the atom-photon field composite system, decoherence is compared with data obtained experimentally by the CQED group at Paris. The SEA-QT method applied in this dissertation provides an alternative and comprehensive explanation to that obtained with the "open system" approach of Quantum Thermodynamics (QT) and its associated quantum master equations of the Kossakowski-Lindblad-Gorini-Sudarshan type. / Ph. D.

Sustainability

resiliency

microgrids

multi-objective optimization

entanglement

decoherence

quantum thermodynamics

steepest-entropy-ascent modeling

Gaussian non-classical correlations in bipartite dissipative continuous variable quantum systems

Quinn, Niall

January 2015

This thesis probes the usefulness of non-classical correlations within imperfect continuous variable decoherent quantum systems. Although a consistent function and practical usefulness of these correlations is largely unknown, it is important to examine their characteristics in more realistic dissipative systems, to gain further insight into any possible advantageous behaviour. A bipartite separable discordant state under the action of controlled loss on one subsystem was considered. Under these conditions the Gaussian quantum discord not only proved to be robust against loss, but actually improves as loss is intensified. Harmful imperfections which reduce the achievable level of discord can be counteracted by this controlled loss. Through a purification an explanation of this effect was sought by considering system-environment correlations, and found that a flow of system-environment correlations increases the quantumness of the state. Entanglement recovery possibilities were discussed and revealed the importance of hidden quantum correlations along bi-partitions across the discordant state and a classically prepared &quot;demodulating&quot; system, acting in such a way as to partially cancel the entanglement preventing noise. Entanglement distribution by separable states was studied by a similar framework, in an attempt to explain the emergence of quantum entanglement by a specific flow of correlations in the globally pure system. Discord appears to play a less fundamental role compared to the qubit version of the protocol. The strengthening of non-classical correlations can be attributed to a flow of classical and quantum correlations. This work proves that discord can be created in unique ways and, in select circumstances, can act to counteract harmful imperfections in the apparatus. Due to this advantageous behaviour discord indeed may ultimately aid in more applicable &quot;real world&quot; applications, which are by definition decoherent.

530.12

Computação quântica baseada em medidas projetivas em sistemas quânticos abertos / Measurement-based quantum computation in open quantum systems

Arruda, Luiz Gustavo Esmenard

20 June 2011

Usamos um modelo exatamente solúvel para calcular a dinâmica da fidelidade de uma computação baseada em medidas projetivas cujo sistema interage com um meio ambiente comum que insere erros de fase. Mostramos que a fidelidade do estado de Cluster canônico oscila como função do tempo e, como consequência, a computação quântica baseada em medidas projetivas pode apresentar melhores resultados computacionais mesmo para um conjunto sequencial de medidas lentas. Além disso, apresentamos uma condição necessária para que a dinâmica da fidelidade de um estado quântico geral apresente um comportamento não-monotônico. / We use an exact solvable model to calculate the gate fidelity dynamics of a measurement-based quantum computation that interacts with a common dephasing environment. We show that the fidelity of the canonical cluster state oscillates as a function of time and, as a consequence, the measurement-based quantum computer can give better computational results even for a set of slow measurement sequences. Furthermore, we present a necessary condition to the fidelity dynamics of a general quantum state presents a non-monotonical shape.

Cluster States

Computação quântica

Decoherence

Descoêrencia

Discórdia quântica

Estados de Cluster

Open quantum systems

Quantum computation

Quantum discord

Sistemas quânticos abertos

Expansão perturbativa para fenômenos a tempos curtos / Perturbative expansion for short-time phenomena

Silva, Ramisés Martins da

27 October 2016

Fenômenos que ocorrem a tempos curtos em sistemas quânticos abertos são caracterizados por possuírem um tempo característico de uma ordem muito menor que o tempo de relaxação do sistema. Como exemplos podemos citar o efeito de decoerência, que em resumo tenta explicar como a natureza quântica de um sistema é perdida ao longo da interação com o ambiente e o fenômeno de superradiância, onde estuda-se como alguns sistemas emitem um pulso energético muito rápido gerando um pico de intensidade fino localizado muito antes da relaxação do sistema. O objetivo desse trabalho é não só estudar esses fenômenos mas como apresentar uma técnica alternativa para a quantificação das medidas associadas e de seus tempos característicos. A técnica apresentada se baseia em fazer uma expansão perturbativa no tempo para o operador densidade a partir de uma equação mestra quântica e com seu uso calcular grandezas físicas relevantes a fenômenos que ocorrem a tempos curtos. A simplicidade da técnica e seu uso abrangente são os principais fatores motivadores deste trabalho. / Short-time phenomena in open quantum systems are characterized by having a characteristic time of a much lower order than the relaxation time of the system. As examples we can mention the effect of decoherence, which in summary tries to explain how the quantum nature of a system is lost along the interaction with the environment and the superradiance phenomenon, where is studied how some systems emit a very fast energy pulse generating a peak of fine intensity located long before the relaxation of the system. The aim of this work is not only study these phenomena but to present an alternative technique for quantifying the associated measures and their characteristic times. The presented technique is based on making a perturbative expansion in time for the density operator from a quantum master equation and use it to calculate physical quantities relevant to phenomena occurring at short times. The simplicity of the technique and its widespread use are the main motivating factors of this work.

Decoerência

Decoherence

Expansão perturbativa

Fenômenos a tempos curtos

Open quantum systems

Perturbative expansion

Short-time phenomena

Sistemas quânticos abertos

Superradiance

Superradiância

Medida da dinâmica de correlações quânticas em ressonância magnética nuclear / Measurement of quantum correlations dynamics in nuclear magnetic resonance

Silva, Isabela Almeida

22 July 2013

Nesta dissertação apresentamos um estudo dos mecanismos de decoerência de sistemas quânticos de Ressonância Magnética Nuclear (RMN) e os seus efeitos sobre a evolução temporal das medidas de correlação não-clássica. Para tal, apresentaremos inicialmente uma revisão bibliográfica sobre alguns dos diversos quantificadores de discórdia quântica, tais como discórdia entrópica, geométrica e negatividade do caráter quântico. Para descrever os canais de atenuação de fase e de amplitude generalizada, que descrevem a relaxação de sistemas de RMN, utilizamos o formalismo de operações quânticas, através da descrição dos operadores de Kraus. As implementações experimentais foram realizadas a partir de sistemas de 2 q-bits descritos por sistemas de RMN de 2 spins 1/2 acoplados via acoplamento J e sistemas de spins 3/2 sujeitos ao acoplamento quadrupolar. Experimentalmente, observamos o surgimento do fenômeno de congelamento (freezing) da discórdia quântica para o sistema de 2 spins 1/2 e o fenômeno de duplo sudden-change em um sistema de spin 3/2. Além disso, propuzemos um método de medida direta para os elementos da matriz densidade de um sistema de 2 spins 1/2 acoplados via acoplamento J, que permite obter toda a informação necessária para o cálculo dos quantificadores de discórdia sem que seja preciso reconstruir completamente a matriz densidade, ou seja, sem empregar o dispendioso método de tomografia de estado quântico (TEQ). / We present a study of the decoherence processes in Nuclear Magnetic Resonance (NMR) quantum systems and their effects on the temporal evolution of non-classical correlations. For that, we review some quantum discord quantifiers, such as entropic and geometric discord as well as negativity of quantumness. To describe the relaxation of NMR systems, we use Kraus operators phase and generalized amplitude damping channels. The experimental demonstrations were achieved in 2 qubits systems implemented by J coupled spins 1/2 as well as spins 3/2 subject to quadrupolar interaction. We demonstrate the freezing phenomenon of quantum discord in a 2 spins 1/2 system, subject to phase and amplitude damping channel, and the phenomenon of double sudden-change in a spin 3/2 system, subject to amplitude damping channel. Furthermore, for spin 1/2 system, we introduce a method to selectively measure density matrix elements, that provide the necessary information to calculate discord quantifiers, without needing the full reconstruction provided by usual quantum state tomography.

Decoherence

Discórdia quântica

Informação quântica

Mecanismos de decoerência

Nuclear magnetic resonance

Quantum discord

Quantum information

Ressonância magnética nuclear

Transferência e manipulação de informação quântica via tunelamento dissipativo não local / State transfer and manipulation of quantum information by nonlocal dissipative tunneling

Moraes Neto, Gentil Dias de

28 May 2013

Nesta tese abordamos o problema de transferência e manipulação de informação quântica em sistemas dissipativos. Inicialmente apresentamos uma técnica para construir, dentro de redes bosônicas dissipativas, canais livres de decoerência (CLD): um grupo de modos normais de osciladores com taxas de amortecimento efetivas nulas. Verificamos que os estados protegidos dentro do CLD definem subespaços livres de decoerência (SLD) quando mapeados de volta para a base dos osciladores naturais da rede. Portanto, a nossa técnica para obter canais protegidos formados por modos normais é uma forma alternativa para construir SLD, que oferece vantagens em relação ao método convencional. Nosso protocolo permite o cálculo de todos os estados da rede protegidos de uma só vez, assim como leva naturalmente ao conceito de subespaço quase livre de decoerência (SQLD), dentro do qual um estado de superposição é quase completamente protegido. O conceito de SQLD, é mais fraco do que a dos SLD, pode proporcionar um mecanismo mais manejável para controlar decoerência. Em seguida desenvolvemos um protocolo para transferência quase perfeita de estados de poláriton de um sistema emissor para um receptor, separados espacialmente, ambos acoplados por um canal de transmissão não ideal que é modelado por uma rede de cavidades dissipativas. Esse protocolo consiste no acoplamento dispersivo entre o estado de poláriton preparado no emissor com os modos normais da rede que forma o canal, o que possibilita que o estado tunele para o receptor. Após a obtenção de um Hamiltoniano efetivo para o acoplamento entre o emissor e receptor, calculamos a fidelidade para a transferência de alguns estados de poláriton, por exemplo, estados tipo gato de Schrödinger. Mostramos que as taxas de decaimento da fidelidade são proporcionais a cooperatividade, parâmetro esse que avalia a relação entre a taxa de dissipação e o acoplamento efetivo. Analisamos a dependência da fidelidade e do tempo de transferência em relação à topologia da rede. Por fim, propomos o mecanismo de tunelamento não local para transferência de estados bosônicos e fermiônicos com alta fidelidade. Demonstramos que a incoerência decorrente das não idealidades quânticas do canal é quase totalmente contornada pelo mecanismo de tunelamento que possibilita um processo de transferência de alta fidelidade. Aplicamos esse mecanismo para transferência e processamento de informações entre múltiplos circuitos quântico (CQs) não ideais. Um conjunto de saídas é simultaneamente acoplado ao conjunto correspondente de entradas de outro QC espacialmente separado do primeiro, através de um único canal quântico não ideal. Mostramos que além da transferência de estados, podemos realizar operações logicas entre qubits distantes e gerar uma pletora de estados quânticos emaranhados. / In this thesis we address the problem of transfer and manipulation of quantum information in dissipative systems. First we present a technique to build, within a dissipative bosonic network, decoherence-free channels (DFCs): a group of normal-mode oscillators with null effective damping rates. We verify that the states protected within the DFC define the wellknown decoherence-free subspaces (DFSs) when mapped back into the natural network oscillators. Therefore, our technique to build protected normal-mode channels turns out to be an alternative way to build DFSs, which offers advantages over the conventional method. It enables the computation of all the network-protected states at once, as well as leading naturally to the concept of the decoherence quasi-free subspace (DQFS), inside which a superposition state is quasi-completely protected against decoherence. The concept of the DQFS, weaker than that of the DFS, may provide a more manageable mechanism to control decoherence. Finally, as an application of the DQFSs, we show how to build them for quasi-perfect state transfer in networks of coupled quantum dissipative oscillators. Then we present a scheme for quasi perfect transfer of polariton states from a sender to a spatially separated receiver, both composed of high-quality cavities filled by atomic samples. The sender and the receiver are connected by a nonideal transmission channel the data bus modelled by a network of lossy empty cavities. In particular, we analyze the influence of a large class of data-bus topologies on the fidelity and transfer time of the polariton state. Moreover, we also assume dispersive couplings between the polariton fields and the data-bus normal modes in order to achieve a tunneling-like state transfer. Such a tunneling-transfer mechanism, by which the excitation energy of the polariton effectively does not populate the data-bus cavities, is capable of attenuating appreciably the dissipative effects of the data-bus cavities. After deriving a Hamiltonian for the effective coupling between the sender and the receiver, we show that the decay rate of the fidelity is proportional to a cooperativity parameter that weigh the cost of the dissipation rate against the benefit of the effective coupling strength. The increase of the fidelity of the transfer process can be achieved at the expense of longer transfer times. We also show that the dependence of both the fidelity and the transfer time on the network topology for distinct regimes of parameters. It follows that the data-bus topology can be explored to control the time of the state-transfer process. Finally we propose the nonlocal tunneling mechanism for high-fidelity state transfer between distant parties. We apply this mechanism for highfidelity information transfer and processing between remote multi-branch nonideal quantum circuits (QCs). We show that in addition to the transfer of states, we can perform logic operations between distant qubits and generate a plethora of entangled quantum states.

Comunicação e informação quântica

Decoerência

Decoherence

Entanglement and quantum nonlocality

Quantum communication and information

Tunelamento

Tunneling

Tratamento algébrico e computacionalmente eficiente para a interação entre sistema e meio ambiente / Algebraic and computationally efficient treatment for the system-environment interaction

Batalhão, Tiago Barbin

26 July 2012

Realizamos nesse trabalho um tratamento abrangente da interação entre um sistema quântico e o meio ambiente modelado como um conjunto de osciladores harmônicos. Partimos para isso de um tratamento prévio de redes de osciladores harmônicos quânticos dissipativos. Utilizando a função característica, transformamos a equação de von Neumann em uma equação diferencial, e explorando a sua linearidade, essa é transformada em uma equação vetorial, cuja resolução é computacionalmente eficiente. Nosso formalismo, que parte de uma rede de osciladores harmônicos, não necessariamente dividida entre sistema e meio ambiente, permite que se contorne a necessidade da hipótese de acoplamento súbito sistema-reservatório para o tratamento exato da evolução do sistema. Em seguida, mostramos que essa evolução pode ser sempre descrita por uma equação mestra na forma usual de Lindblad, embora os coeficientes que a definem possam ser dependentes do tempo. Isso abre novas possibilidades para a dinâmica do sistema, e leva a efeitos que podem ser classificados de não-Markovianos, embora sejam descritos por uma equação mestra completamente local no tempo. Ressaltamos que, por ser baseado em uma solução exata, o método pode ser aplicado para qualquer intensidade de acoplamento, e é consideravelmente mais simples do que outros métodos disponíveis para esse fim, como os baseados em integrais de trajetória. Por fim, utilizamos simulações computacionais para explorar a validade das aproximações de ondas girantes e de Born-Markov, e os fenômenos que podem ser observados nos regimes em que elas deixam de ser válidas. / We present a comprehensive treatment of the interaction of a quantum system with an environment modeled as a set of harmonic oscillators. We start from a previous treatment of a network of quantum dissipative harmonic oscillators. Using the characteristic function, we transform the von Neumann equation in a differential equation, and exploring its linearity, this is transformed in a vector equation, whose solution is computationally efficient. Our method, whose origin lies on a network not necessarily divided into system and reservoir, allows us to circumvent the necessity of the sudden-coupling approximation for the exact treatment of the system evolution. After this, we show that this dynamics can always be described by a master equation in standard Lindblad form, although its coefficients may be functions of time. This opens new possibilities for the system dynamics, and lead to effects that may be called non-Markovian, even if they are described by a completely local-in-time master equation. It should be emphasized that, as it is based on an exact solution, the method may be applied for any strength of the system-reservoir interaction, and it is considerably simpler than other available methods, such as those based on path integrals. Finally, we employ computer simulations to investigate the validity of the rotating-wave and Born-Markov approximations, and the phenomena that migth be observed in regimes in which they fail to be valid.

Decoerência

Decoherence

Dissipação quântica

Equações mestras quânticas

Networks of dissipative oscillators

Quantum Dissipation

Quantum master equations

Redes de osciladores dissipativos