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Open quantum systemsGranlund Gustafsson, Anton January 2023 (has links)
In this Bachelor thesis project, the Lindblad master equation is derived, both as the most general way of modeling interaction with an environment that lacks memory, and through microscopic derivations focused on assumptions about the way the system interacts with its environment (weak-coupling, Born-Markov and rotating wave approximations). It is then applied to a two-level system (qubit).
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Weak mutually unbiased bases with applications to quantum cryptography and tomography. Weak mutually unbiased bases.Shalaby, Mohamed Mahmoud Youssef January 2012 (has links)
Mutually unbiased bases is an important topic in the recent quantum system
researches. Although there is much work in this area, many problems
related to mutually unbiased bases are still open. For example, constructing
a complete set of mutually unbiased bases in the Hilbert spaces with composite
dimensions has not been achieved yet. This thesis defines a weaker
concept than mutually unbiased bases in the Hilbert spaces with composite
dimensions. We call this concept, weak mutually unbiased bases. There is
a duality between such bases and the geometry of the phase space Zd × Zd,
where d is the phase space dimension. To show this duality we study the
properties of lines through the origin in Zd × Zd, then we explain the correspondence
between the properties of these lines and the properties of the
weak mutually unbiased bases. We give an explicit construction of a complete
set of weak mutually unbiased bases in the Hilbert space Hd, where
d is odd and d = p1p2; p1, p2 are prime numbers. We apply the concept of
weak mutually unbiased bases in the context of quantum tomography and
quantum cryptography. / Egyptian government.
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Signatures of topological phases in an open Kitaev chain / Tecken på topologiska faser i en öppen Kitaev kedjaErmakova, Natalia January 2021 (has links)
Some physical systems exhibit topological properties in the form of topological invariants— features of the system that remain constant unless the system undergoessignificant changes i.e. changes that require closing the energy gap of the Hamiltonian.This work studies one example of a system with topological properties — a Kitaevchain. Here, this model is studied when it is coupled to an environment. We studythe effect of the coupling on the topology of the system and attempt to find signaturesof topological phases in the dynamics of the system. By using the Lindblad equationdefined in the formalism of third quantization, we study the time evolution of thesystem numerically by using the Euler method. We find that the dynamics of theentanglement spectrum of half of the chain is different in the topological and trivialphases: if the system undergoes a quench from trivial to topological phase, the entanglementspectrum exhibits crossings as the system evolves in time. We also studythe topological phases when disorder is added to the system. We test the stabilityof the topological phases of the system against disorder and find that the topologicalphases are not affected by a weak disorder. Moreover, by studying the statistics of theminimum entanglement spectrum gap, we find that, in general, a stronger disordermakes the crossings less likely to appear in the topological phase and more likely toappear in the trivial phase. / Det finns fysiska system som visar topologiska egenskaper i form av topologiska invarianter,som ändras inte så länge systemet genomgår ändringar som inte stängerHamiltonianens energigap. I det här arbetet undersöker vi ett exempel av ett systemmed topologiska egenskaper — en Kitaev kedja. Denna modell är studerat närden är kopplad till en omgivning. Vi undersöker kopplingens påverkan på systemetstopologi och vi försöker hitta tecken på topologiska faser i systemets dynamik. Vianvänder Lindblads ekvation definierat i tredje kvantiserings formalism för att studerasystemets tidsutveckling numeriskt, genom att använda Eulers metod. Vi upptäckeratt det finns skillnader i tidsutveckling av kvantsammanflätningsspektrumav häften av kedjan som beror på systems topologiska fas. Om systemet genomgåren kvantsläckning från den triviala till den topologiska fasen, kommer det finnas korsningari kvantsammanflätningensspektrum som uppstår under dess tidsutveckling.Dessutom studerar vi de topologiska faserna när det finns oordning i systemet. Viundersöker topologiska fasernas stabilitet mot oordning och upptäcker att en svagoordning påverkar inte de topologika faserna. Dessutom, genom att studera den minstakvantsammanflätningsspektrumsgap upptäcker vi att en starkare oordning ledertill kvantsammanflätningsspektrumskorsningar att vara mindre sannolika i den topologiskafasen och mer sannolika i den triviala fasen.
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Hierarchical equations of motion for open quantum systems consisting of many energy states / 大規模量子散逸系を対象とした階層型運動方程式の開発Nakamura, Kiyoto 23 March 2022 (has links)
京都大学 / 新制・課程博士 / 博士(理学) / 甲第23731号 / 理博第4821号 / 新制||理||1689(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授 谷村 吉隆, 教授 林 重彦, 教授 渡邊 一也 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM
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Dissipative State Engineering in Quantum Many-Body SystemsSchnell, Alexander 12 September 2019 (has links)
Quantum systems that are in weak contact with a thermal heat bath will ultimately relax to an equilibrium state which is characterized by the temperature of the environment only. This state is independent of the specific properties of the bath and of how it is coupled to the system. This changes completely, when the system is additionally driven. Such a driven-dissipative situation can emerge, for example, due to an additional time-periodic modulation of the system, or when it is brought into contact with a second bath of different temperature. Then, the system will run into a well-defined nonequilibrium steady state. This state, however, will depend on the very details of the environment and its coupling to the system.
We study whether this freedom can be used to engineer interesting properties of quantum systems, which are not found in their equilibrium states, i.e. in the absence of a drive. We focus on bosonic quantum many-body systems. We investigate when far-from-equilibrium ideal gases feature Bose condensation in a group of single-particle states, as opposed to situations where Bose condensation is completely absent in the nonequilibrium steady state. We show that Bose condensation can be induced in a finite one-dimensional ideal gas by the competition of two heat baths whose temperatures both lie well above the equilibrium condensation temperature.
This setup also allows to engineer condensation in excited single-particle states. We discuss first ideas to study similar setups in weakly interacting Bose gases. Describing the microscopic dynamics of interacting many-body systems coupled to thermal baths is extremely challenging, due to the fact that generally the full many-body spectrum is inaccessible. Using ideas from semiclassics, we develop an approximation to the dynamics that yields good results at high and intermediate bath temperatures.
We also investigate the transient dynamics of driven-dissipative quantum systems. Our studies are motivated by a result that is well known for isolated quantum systems: for a system whose dynamics is generated by a time-periodic Hamiltonian, the stroboscopic dynamics (observed at integer multiples of the driving period) can always be understood as if it would stem from a time-independent Hamiltonian, the Floquet Hamiltonian. For open quantum systems in contact with an environment, we ask if a similar mapping to an effective generator, the Floquet Lindbladian, is always possible. For a simple qubit model we show that there are two extended parameter regions, one in which the Floquet Lindbladian exists, and one in which it does not. We discuss problems of analytical expansions that can give rise to this Floquet Lindbladian and discuss how we can interpret the region where it does not exist.
These results are important for dissipative Floquet engineering and open up new perspectives for the control of open quantum systems via time-periodic driving.:1. Introduction
2. Master equation for open quantum systems
3. Existence of the Floquet Lindbladian
4. Number of Bose-selected modes in driven-dissipative ideal Bose gases
5. High-temperature nonequilibrium Bose condensation induced by a hot needle
6. Weakly interacting Bose gases far from thermal equilibrium
7. Summary and outlook / Quantensysteme, die in schwacher Wechselwirkung mit einem thermischen Wärmebad stehen, relaxieren stets in einen Gleichgewichtszustand, welcher allein durch die Temperatur der Umgebung beschrieben ist. Dieser Zustand ist unabhängig von den spezifischen Eigenschaften des Bades, und davon wie dieses an das System gekoppelt ist. Dies ändert sich, wenn das System zusätzlich angetrieben wird. Ein solches getrieben-dissipatives Szenario kann beispielsweise durch einen zusätzlichen zeitperiodischen Antrieb entstehen, oder wenn das System mit einem zweiten Bad unterschiedlicher Temperatur in Kontakt gebracht wird. In diesem Fall läuft das System in einen wohldefinierten stationären Nichtgleichgewichtszustand. Dieser Zustand hängt jedoch von den Details der Umgebung, und davon wie diese an das System gekoppelt ist, ab.
Es wird untersucht ob diese Freiheit genutzt werden kann um interessante Eigenschaften von Quantensystemen zu konstruieren, die in deren Gleichgewichtszuständen, d.h. in Abwesenheit des Antriebs, nicht zu finden sind. Der Fokus der Arbeit liegt auf bosonischen Quantenvielteilchensystemen. Es wird ergründet unter welchen Bedingungen ideale Gase fernab des thermischen Gleichgewichts Bose Kondensation in einer Gruppe von Einteilchenzuständen aufweisen, im Gegensatz zu Szenarien in denen überhaupt keine Bose Kondensation im stationären Nichtgleichgewichtszustand auftritt. Weiterhin wird gezeigt, dass Bose Kondensation in einem eindimensionalen idealen Gas durch das Wechselspiel zweier Wärmebäder induziert werden kann. Die Temperatur beider Bäder liegt dabei weit über der Kondensationstemperatur des Gleichgewichts. Diese Anordnung erlaubt außerdem kontrollierte Kondensation in angeregten Einteilchenzuständen. Erste Ideen für das theoretische Studium ähnlicher Anordnungen für schwach wechselwirkende Bosegase werden diskutiert. Eine Beschreibung der mikroskopischen Dynamik wechselwirkender Vielteilchensysteme ist extrem anspruchsvoll, da typischerweise das volle Vielteilchenspektrum unzugänglich ist. Unter Zurhilfenahme semiklassischer Ideen wird eine Näherung der Dynamik entwickelt, welche eine gute Beschreibung für hohe und intermediäre Temperaturen liefert.
Weiterhin wird die transiente Dynamik getrieben-dissipativer Quantensysteme untersucht. Die Motivation bietet ein bekanntes Resultat für abgeschlossene Quantensysteme: Für ein System, dessen Dynamik durch einen zeitperiodischen Hamiltonoperator bestimmt ist, kann die stroboskopische Dynamik (unter Beobachtung zu Zeiten, die Vielfache der Antriebsperiode sind) immer so verstanden werden als würde sie von einem zeitunabhängigen Hamiltonoperator, dem Floquet Hamiltonian, induziert. Für offene Quantensysteme im Kontakt mit einer Umgebung wird untersucht ob eine ähnliche Abbildung auf einen effektiven Generator, den Floquet Lindbladian, existiert. Für ein einfaches Qubit Modell wird gezeigt, dass es zwei ausgedehnte Parameterregionen gibt, eine in welcher der Floquet Lindbladian existiert und eine weitere in der dieser nicht existiert. Es werden Probleme von analytischen Entwicklungen des Floquet Lindbladian diskutiert. Auch wird eine Interpretation der Region gegeben, in der dieser nicht existiert.
Diese Resultate sind maßgeblich für dissipatives Floquetengineering und eröffnen neue Blickwinkel auf die zeitperiodische Kontrolle offener Quantensysteme.:1. Introduction
2. Master equation for open quantum systems
3. Existence of the Floquet Lindbladian
4. Number of Bose-selected modes in driven-dissipative ideal Bose gases
5. High-temperature nonequilibrium Bose condensation induced by a hot needle
6. Weakly interacting Bose gases far from thermal equilibrium
7. Summary and outlook
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Phase space methods in finite quantum systemsHadhrami, Hilal Al January 2009 (has links)
Quantum systems with finite Hilbert space where position x and momentum p take values in Z(d) (integers modulo d) are considered. Symplectic tranformations S(2ξ,Z(p)) in ξ-partite finite quantum systems are studied and constructed explicitly. Examples of applying such simple method is given for the case of bi-partite and tri-partite systems. The quantum correlations between the sub-systems after applying these transformations are discussed and quantified using various methods. An extended phase-space x-p-X-P where X, P ε Z(d) are position increment and momentum increment, is introduced. In this phase space the extended Wigner and Weyl functions are defined and their marginal properties are studied. The fourth order interference in the extended phase space is studied and verified using the extended Wigner function. It is seen that for both pure and mixed states the fourth order interference can be obtained.
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Relaxation in harmonic oscillator systems and wave propagation in negative index materialsChimonidou, Antonia 02 June 2010 (has links)
This dissertation is divided up into two parts, each examining a distinct
theme. The rst part of our work concerns itself with open quantum systems and
the relaxation phenomena arising from the repeated application of an interaction
Hamiltonian on systems composed of quantum harmonic oscillators. For the second
part of our work, we shift gears and investigate the wave propagation in left-handed
media, or materials with simultaneously negative electric permeability and magnetic
permeability . Each of these two parts is complete within its own context.
In the rst part of this dissertation, we introduce a relaxation-generating
model which we use to study the process by which quantum correlations are created when an interaction Hamiltonian is repeatedly applied to bipartite harmonic oscillator
systems for some characteristic time interval . The two important time scales
which enter our results are discussed in detail. We show that the relaxation time
obtained by the application of this repeated interaction scheme is proportional to
both the strength of interaction and to the characteristic time interval . Through
discussing the implications of our model, we show that, for the case where the oscillator
frequencies are equal, the initial Maxwell-Boltzmann distributions of the
uncoupled parts evolve to a new Maxwell-Boltzmann distribution through a series
of transient Maxwell-Boltzmann distributions, or quasi-stationary, non-equilibrium
states. We further analyze the case in which the two oscillator frequencies are unequal
and show how the application of the same model leads to a non-thermal steady
state. The calculations are exact and the results are obtained through an iterative
process, without using perturbation theory.
In the second part of this dissertation, we examine the response of a plane
wave incident on a
at surface of a left-handed material, a medium characterized
by simultaneously negative electric permittivity and magnetic permeability . We
do this by solving Maxwell's equations explicitly. In the literature up to date,
it has been assumed that negative refractive materials are necessarily frequency
dispersive. We propose an alternative to this assumption by suggesting that the
requirement of positive energy density can be relaxed, and discuss the implications
of such a proposal. More speci cally, we show that once negative energy solutions
are accepted, the requirement for frequency dispersion is no longer needed. We
further argue that, for the purposes of discussing left-handed materials, the use of
group velocity as the physically signi cant quantity is misleading, and suggest that
any discussion involving it should be carefully reconsidered. / text
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Gaussian non-classical correlations in bipartite dissipative continuous variable quantum systemsQuinn, Niall January 2015 (has links)
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 "demodulating" 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 "real world" applications, which are by definition decoherent.
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Computação quântica baseada em medidas projetivas em sistemas quânticos abertos / Measurement-based quantum computation in open quantum systemsArruda, Luiz Gustavo Esmenard 20 June 2011 (has links)
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.
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Expansão perturbativa para fenômenos a tempos curtos / Perturbative expansion for short-time phenomenaSilva, Ramisés Martins da 27 October 2016 (has links)
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.
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