Entanglement and energy level crossing of spin and Fermi Hamilton operators

De Greef, Jacqueline

24 July 2013

M.Sc. (Applied Mathematics) / Entanglement is a quantum resource with applications in quantum communication as well as quantum computing amongst others. Since quantum entanglement is such an abstract concept numerous mathematical measures exist. Some of these have a purely theoretic purpose whereas others play a role in describing the magnitude of entanglement of a system. In quantum systems energy level crossing may occur. Energy levels in quantum systems tend to repel each other so when any type of degeneracy occurs where the energy levels coalesce or cross it is of interest to us. Two such points of degeneracy are exceptional and diabolic points. When these occur it is useful to investigate these points in specific systems and observe level crossing. In this thesis we mainly investigate the relationship between entanglement, energy level crossing and symmetry as well as the exceptional and diabolic points of specific systems. We are especially interested in systems described by spin and Fermi operators.

Quantum entanglement

Spin operators

Hamilton operator

Fermi Hamilton operators

Energy levels (Quantum mechanics)

Quantum theory

Linear operators

The application of spontaneous parametric downconversion to develop tools for validating photonic quantum information technologies

Thomas, Peter James

January 2010

This portfolio of work contributes to the remit of the National Physical Laboratory (NPL) to develop the underpinning expertise and tools for validating nascent and future optical quantum technologies based on the discrete and quantum properties of photons. This requirement overlaps with the requirement to provide validation for devices operating in the photon-counting regime. A common theme running through the portfolio is photon pairs generated through spontaneous parametric downconversion (SPDC). A Hong-Ou-Mandel (HOM) interferometer sourced with visible wavelength photon pairs from an SPDC process in beta-barium borate (BBO) was designed, built and characterised. The visibility of the HOM interference is dependent on the indistinguishability of the interfering photons, but is also influenced by imperfections of the interferometer; therefore an investigation was carried out to quantify the effects of the interferometer imperfections on the measured visibility so that the true photon indistinguishability could be measured with a quantified uncertainty. A bright source of correlated pair photons in the telecoms band based upon a pump enhanced SPDC process in periodically-poled potassium titanyl phosphate (PPKTP) was designed, built and characterised. From the characterisation measurements the source brightness was estimated to be 6.2×10⁴ pairs/ s/ mw pump. The photon pairs were further characterised through their incorporation as a source in a HOM interference experiment. The developed correlated photon pair source was at the heart of a novel scheme for the generation of polarisation entangled photon pairs, for which the design, build and characterisation work is presented. The source was demonstrated to produce two of the four maximally entangled Bell states with quantum interference visibilities of around 0.95. The generated states were also shown to break a form of Bell's inequality by around six standard deviations. The polarisation entangled photon pair source was originally built at the University of St Andrews and was later transferred to the NPL where it will extend NPL's capabilities to this key spectral region. Finally a study was carried out to investigate the possibility of a wavelength tuneable device for the absolute measurement of single photon detector quantum efficiencies based upon an established SPDC technique.

623

Estudo da dinâmica de sistemas quânticos compostos sob a influência de ambientes externos / Study of the dynamics of composite quantum systems under the influence of external environments

Deçordi, Gustavo Lázero, 1986-

05 December 2016

Orientador: Antonio Vidiella Barranco / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-08-31T02:56:15Z (GMT). No. of bitstreams: 1 Decordi_GustavoLazero_D.pdf: 2456755 bytes, checksum: 42a17eacb2e1a86e81888e48272ed08e (MD5) Previous issue date: 2016 / Resumo: Estudamos nesta tese, sistemas quânticos compostos sob a influência de ambientes externos. Na primeira parte do trabalho, investigamos um sistema de dois qubits interagentes, estando um deles isolado e o outro acoplado a um banho térmico. Analisamos os efeitos da temperatura do banho sobre a dinâmica do sistema de dois qubits. Com essa finalidade, empregamos dois modelos distintos da interação sistema-ambiente: i) um modelo microscópico, no qual a equação mestra é obtida levando-se em conta o acoplamento entre os qubits na dedução do termo dissipativo, ii) um modelo fenomenológico, no qual o termo dissipativo é simplesmente adicionado ao termo unitário da equação de evolução do operador densidade. Obtemos soluções analíticas para os modelos, o que permitiu estudá-los em um intervalo considerável do acoplamento entre os qubits. Dedicamos a segunda parte do trabalho ao estudo de um sistema quântico em particular acoplado a um pequeno ambiente. Neste contexto, resolvemos exatamente o modelo da interação radiação-matéria conhecido como modelo de Tavis-Cummings a dois átomos. De posse das soluções, obtidas em circunstâncias bastante gerais e até então não encontradas na literatura, investigamos os efeitos oriundos da interação de um pequeno ambiente (átomo em estado de mistura estatística) sobre a dinâmica do subsistema composto pelo outro átomo acoplado ao modo do campo eletromagnético. Nós mostramos que propriedades não-clássicas associadas ao sistema principal podem ser significativamente degradadas pela ação do ambiente quando o átomo 2 está acoplado de maneira resonante ao campo. Encontramos que o comportamento não-clássico do sistema pode ser restaurado a medida que dessintonizamos o campo da frequência de transição do átomo 2, o ambiente / Abstract: We study in this thesis composite quantum systems under the influence of external environments. In the first part of this work, we investigate a two qubit interacting system having one of them isolated and the other coupled to a thermal bath. We analyze the effect of the temperature of the bath on the dynamics of the two qubit system. In order to do that, we consider two different models of system-reservoir interaction: i) a "microscopic" model, in which the master equation is derived taking into account the interaction between the two subsystems (qubits), ii) a "phenomenological" approach, in which the master equation consists of a dissipative term added to the unitary evolution term. We show that in the strong coupling regime between the subsystems (qubits), the expected thermal equilibrium steady state for the two-qubit system naturally arises in the framework of the microscopic model, while in the phenomenological approach it is obtained a steady state density operator which is not correct. Furthermore, the differences are even more profound in the weak coupling regime, when the models give rise to opposite behaviors with regard to the linear entropy of qubit 1. At the context of quantum systems coupled to environments with few degrees of freedom, we solve analytically the matter-radiation interaction model known as two atom Tavis-Cummings Model. With the solutions at hand, achieved in general circumstances until the present not found in literature, in which the constituent atoms may be coupled with different strengths to the field and also have different frequency detunings, we study the effects that arise from the interaction of a small environment (atom in a statistical mixture state) with the other atom coupled to an oscillator (cavity mode). We show that nonclassical features associated to the main system may be significantly degraded by the action of the small environment, if atom 2 is resonantly coupled to the field. We also demonstrate that the nonclassical behaviour of the system may be restored if we detune the field from the transition frequency of atom 2, the environment / Doutorado / Física / Doutor em Ciências / 899872/2011 / CAPES

Sistemas quânticos

Ótica quântica

Emaranhamento quântico

Jaynes-Cummings, Modelo

Quantum systems

Quantum optics

Quantum entanglement

Jaynes-Cummings model

Numerical Study of the Fractional Quantum Hall Effect: a Few-Body Perspective

Bin Yan (6622667)

15 May 2019

<div><div><div><p>When confined to a finite, two-dimensional area and exposed to a strong magnetic field, electrons exhibit a complicated, highly correlated quantum behavior known as the quantum Hall effect. This dissertation consists of finite size numerical investigations of this effect. One line of study develops treatment of the fractional quantum Hall effect using the hyperspherical method, in conjunction with applications to the few-body quantum Hall systems, e.g., highly-controlled atomic systems. Another line of research fully utilizes the developed numerical techniques to study on the platform of finite size fractional quantum Hall states the bulk-edge correspondence principle, which is universal for phases in topological orders. It has been demonstrated that the eigenstates associated with the entanglement spectrum reveal more information about the ground state than the spectrum alone.</p></div></div></div>

Atomic Physics

Condensed Matter Physics

Few-body quantum Hall effect

Entanglement spectrum

Bulk-edge correspondence

Hyperspherical Coordinates

Vers les technologies quantiques basées sur l’intrication photonique / Towards quantum applications based on photonic entanglement

Vergyris, Panagiotis

28 November 2017

Le but de cette thèse est de développer des sources d’intrication photonique en vue d'applications en sciences information quantique. Dans ce contexte, nous présentons une source très performante et entièrement guidée permettant, au moyen d'une boucle de Sagnac, la génération d'états hyper-intriqués en polarisation et en énergie-temps. La configuration guidée rend le dispositif versatile, efficace et compatible avec une large bande spectrale, répondant ainsi au besoin des systèmes et réseaux de communication fibrés. À cette fin, nous avons distribué simultanément dans différents canaux télécoms des paires de photons hyper-intriqués au moyen de multiplexeurs en longueur d'onde à 5 canaux (DWDM), augmentant de fait le débit. La qualité de l'intrication est validée par la violation d'une inégalité de Bell étendue à un espace de Hilbert à 16 dimensions. Afin de pouvoir interfacer des photons aux longueurs d'ondes des télécommunications avec les bandes d'absorption des mémoires quantiques situées dans le visible, nous avons également développé une interface cohérente en longueur d'ondes. Un nouveau dispositif de métrologie quantique permettant la mesure avec une précision inégalée des effets de la dispersion chromatique dans les fibres optiques standards est également proposé. Notre approche "quantique" améliore la précision par un facteur 2.6 par rapport aux méthodes de mesures conventionnelles. Dans ce même contexte, nous avons aussi implémenté un nouveau protocole de métrologie de la phase de deux photons en ne détectant uniquement qu'un seul photon. Cette réalisation ouvre la voie à des applications potentielles simples s'appuyant sur peu de ressources au niveau de la détection. Finalement, dans la perspective de la miniaturisation de dispositifs quantiques, nous avons démontré un générateur d'intrication annoncée intégré sur puce qui trouve des applications en calcul et métrologie quantique. / The aim of this thesis was to develop photonic entanglement sources and study their implementation in the general field of quantum information technologies. To this end, a novel fully wave-guided, high performance photonic entanglement source is presented, able to generate hyper-entangled states in the observables of polarization and energy-time by means of a nonlinear Sagnac loop. The waveguide-based design makes it flexible, reliable, and adaptable to a wide spectral range, paving the way towards compact photonic entanglement generators, compatible with fiber-based communication systems and networks. This has been underlined by generating and distributing hyperentanglement in 5x2 dense wavelength division multiplexed channel telecom pairs, simultaneously, towards higher bit rates. The quality of the generated entanglement has been qualified by violating the Bell inequalities in a 16-dimension Hilbert space. Moreover, to adapt the wavelength of the entangled telecom photon pairs to the absorption wavelength of current quantum memory systems, a coherent wavelength converter is demonstrated. Furthermore, within the framework of quantum metrology, a new concept for a high-precision chromatic dispersion (CD) measurement in standard single mode fibers is introduced and demonstrated. In this demonstration, due to conceptual advantages enabled by quantum optics, an unprecedented 2.6 times higher accuracy on CD measurements is shown, compared to state-of-the-art techniques. In the same context, a new protocol for measuring two-photon phase shifts is performed using single photon detection only, promising scalable and potential real device applications with limited resources and simplified detection schemes. Finally, any potential application of quantum optics will be realized using small-scale devices. In this framework, an integrated on-chip heralded path entanglement generator is demonstrated, and shown to be adaptable to logic gate operations.

Optique intégrée

Guides PPLN

Optique quantique

Intrications quantiques

Interférences quantiques

Integrated optics

PPLN waveguides

Quantum optics

Quantum entanglement

Quantum interference

Génération et manipulation d'états photoniques intriqués pour la communication et la métrologie quantiques / Generation and manipulation of entangled photonic states for quantum communication and metrology

Mazeas, Florent

12 November 2018

Après une première révolution quantique marquée par l'avènement de la physique quantique et de ses lois contre-intuitives, le monde du XXIe siècle est en proie à une seconde révolution articulée autour des technologies quantiques. Ces dernières promettent un bouleversement important dans les domaines de la communication, du calcul, de la simulation et de la métrologie. Dans cette thèse, nous abordons deux des quatre sous-domaines cités précédemment, à savoir ceux de la communication et de la métrologie quantique. Le mot d'ordre rassemblant ces travaux est l'intrication. En effet, nous montrons que, grâce à cette propriété fondamentale, les performances des systèmes de communication et de métrologie standards peuvent être surpassés. Ainsi, nous présentons comment générer ces états intriqués responsables de l'avantage quantique, et ce sur différentes plateformes technologiques. La première plateforme exploitée est le silicium. Récente pour la photonique, elle combine des avantages de maturité permettant l'intégration de nombreuses structures micrométriques sur une même puce, avec des propriétés non-linéaires, basés sur des processus d'ordre 3, efficaces. Le silicium se destine alors à de nombreuses applications comme nous le montrons en générant des paires de photons intriqués démultiplexés spectralement et directement compatibles avec les réseaux de télécommunications standards. La seconde plateforme que nous présentons est le niobate de lithium. Cette dernière, très exploitée dans bon nombres de travaux en photonique quantique, possède une efficacité de génération de paires de photons intriqués très importante, notamment grâce à l'exploitation de processus non-linéaires d'ordre 2. Nous détaillons une expérience de génération d'états hyper-intriqués, qui, à l'instar du silicium, est orientée vers le domaine de la communication quantique. Enfin, nous exploitons aussi ces paires de photons intriqués combinés à des méthodes d'interférométrie quantique afin de réaliser une expérience de métrologie quantique. Le but de cette dernière étant de mesurer avec une précision inédite la différence d'indices de réfraction de fibres bi-coeurs. / After a first quantum revolution marked by the advent of quantum physics and its counter-intuitive laws, the XXIst century is in the throes of a second quantum revolution based on quantum technologies. These promises a major upheaval in the areas of communication, calculation, simulation and metrology. In this thesis, we address two of the four subdomains mentioned above, namely those of communication and quantum metrology. The main word bringing together these works is entanglement. Indeed, we show that, thanks to this fundamental property, the performances of standard communication and metrology systems can be surpassed. Thus, we present how to generate these entangled states responsible for the quantum advantage, and this on two technological platforms. The first platform exploited is silicon. The latter, recent for photonics, combines the advantages of maturity allowing the integration of many micrometric structures on the same chip, with efficient non-linear properties, based on third order process. Silicon is then destined for many applications as we show by generating pairs of spectrally demultiplexed entangled photons directly compatible with standard telecommunication networks. The second platform we present is lithium niobate. The latter, widely used in many quantum photonics demonstrations, has a very important efficiency of entangled photon pairs generation, notably thanks to the exploitation of second order non-linear process. We detail an experiment of hyper-entangled states generation, which, like silicon, is oriented towards the domain of quantum communication. Finally, we also exploit these pairs of entangled photons combined with quantum interferometry methods to realize a quantum metrology experiment. The purpose is to measure with unprecedented precision the refractive indices difference of dual-core fibers.

Technologies quantiques

Communication quantique

Métrologie quantique

Intrication

Photonique sur silicium

Quantum technologies

Quantum communication

Quantum metrology

Entanglement

Silicon photonics

Towards testing Bell's inequality using atoms correlated in momentum / Vers la réalisation du test d’inégalité de Bell avec les atomes corrèle en impulsion

Imanaliev, Almazbek

30 March 2016

Ce manuscrit décrit des expériences d’optique atomique quantique utilisant un détecteur résolu en impulsions d’atomes uniques d’hélium métastable. La première partie du manuscrit décrit la mesure de cohérence de deuxième ordre de la superradiance à partir d’un condensat de Bose-Einstein d’helium métastable. Bien que le condensat soit cohérent et le gain du processus de superradiance élevé, celle-ci montre toujours une statistique thermique comme celle de l’émission spontanée. La suite du manuscrit est dédiée au test de la non localité d’une source atomique corrélée en impulsion. Le schéma du test s’inspire d’une réalisation faite par Rarity et Tapster sur des photons intriqués en impulsion. Les ingrédients principaux d’un tel schéma sont la source atomique générée par instabilité dynamique du condensat dans un réseau optique en mouvement, le contrôle cohérent des atomes par diffraction de Bragg et la mesure de la corrélation des atomes dans les différentes voies de sortie du schéma interférométrique. Un point clé est le contrôle et la manipulation de la phase des ondes atomiques. Le chapitre 3 décrit les tests sur le contrôle cohérent par diffraction de Bragg et leurs résultats encourageants. La nature non classique de notre source atomique est démontrée par l’observation d’une interférence à deux particules en les envoyant sur une séparatrice atomique. Cet analogue atomique de l’expérience de Hong Ou et Mandel est le sujet du dernier chapitre de ce manuscrit. Le résultat de cette expérience ouvre la possibilité du test d’inégalité de Bell avec des particules massives corrélées sur des degrés de liberté externe. / This manuscript describes quantum atom optics experiments using metastable helium atoms with a single-atom momentum resolved detector. In the first part of this manuscript, the second order correlation measurement of the superradiance from a metastable helium Bose-Einstein condensate is presented. The superradiance effect is the collective radiation of dense ensemble where a strong gain of the radiation is expected. We have shown the thermal like statistics of the emission even in the presence of the strong gain. The next part of the manuscript is devoted to the quantum nonlocality test using a pair of atoms entangled in momentum. The protocol we came up with is inspired from the one of Rarity and Tapster with pairs of photons entangled in momentum. The essential ingredients of this protocol are the atomic pair produced by dynamical instability of the Bose-Einstein condensate in a moving optical lattice, the coherent control of the atomic pair by Bragg diffraction and the correlation measurement of the atoms in different output modes of the interferometric protocol. The experimental characterization and preparation of coherent control by Bragg diffraction are presented showing the proof of principle of such a protocol. The last part of the manuscript discusses the realization of the atomic Hong-Ou-Mandel experiment using the same atomic pair with an atomic beamsplitter. The non-classical interference result of this experiment has opened an opportunity for us to realize Bell’s inequality test with massive particles correlated in external degrees of freedom.

Condensat de Bose-Einstein

Superradiance

Inégalité de Bell

Indiscernabilité

Intrication

Corrélation

Bose-Einstein condensate

Superradiance

Bell's inequality

Indistinguishability

Entanglement

Correlation

530.12

Transversal Construction of Topological Gates on Multiqubit Quantum Codes

Chauwinoir, Sheila

January 2022

We study the possibility of constructing quantum gates using topological phases, which originate from local SU(2) evolution of entangled multiqubit systems. For this purpose, logical codewords using two-, three- and nine-qubit entangled states are defined and possible implementations of topological gates on these codes, are examined. For two-qubit systems, it is shown that for only two of the Pauli gates, a topological implementation is possible, the third must be non-topological. Furthermore, it is shown that a topological implementation of Hadamard gate is also possible on the two-qubit code. For the three-qubit code, the logical Pauli gates are found to be topologically implementable and a topological implementation of the logical S gate seems to be possible as well. Lastly, for the nine-qubit code, the logical Pauli gates, the logical S gate and the logical T gate are shown to be implementable topologically on the code. It remains an open question whether topological implementation of logical Hadamard gate by invertible local operators is possible on the nine-qubit code.

entanglement

local SU(2) evolution

topological phase factors

topological gates

transversal gates

multiqubit quantum codes

Hopf fibration

Physical Sciences

Fysik

Entanglement certification in quantum many-body systems

Costa De Almeida, Ricardo

07 November 2022

Entanglement is a fundamental property of quantum systems and its characterization is a central problem for physics. Moreover, there is an increasing demand for scalable protocols that can certify the presence of entanglement. This is primarily due to the role of entanglement as a crucial resource for quantum technologies. However, systematic entanglement certification is highly challenging, and this is particularly the case for quantum many-body systems. In this dissertation, we tackle this challenge and introduce some techniques that allow the certification of multipartite entanglement in many-body systems. This is demonstrated with an application to a model of interacting fermions that shows the presence of resilient multipartite entanglement at finite temperatures. Moreover, we also discuss some subtleties concerning the definition entanglement in systems of indistinguishable particles and provide a formal characterization of multipartite mode entanglement. This requires us to work with an abstract formalism that can be used to define entanglement in quantum many-body systems without reference to a specific structure of the states. To further showcase this technique, and also motivated by current quantum simulation efforts, we use it to extend the framework of entanglement witnesses to lattice gauge theories. / L'entanglement è una proprietà fondamentale dei sistemi quantistici e la sua caratterizzazione è un problema centrale per la fisica. Inoltre, vi è una crescente richiesta di protocolli scalabili in grado di certificare la presenza di entanglement. Ciò è dovuto principalmente al ruolo dell'entanglement come risorsa cruciale per le tecnologie quantistiche. Tuttavia, la certificazione sistematica dell'entanglement è molto impegnativa, e questo è particolarmente vero per i sistemi quantistici a molti corpi. In questa dissertazione, affrontiamo questa sfida e introduciamo alcune tecniche che consentono la certificazione dell'entanglement multipartito in sistemi a molti corpi. Ciò è dimostrato con un'applicazione a un modello di fermioni interagenti che mostra la presenza di entanglement multipartito resiliente a temperature finite. Inoltre, discutiamo anche alcune sottigliezze riguardanti la definizione di entanglement in sistemi di particelle indistinguibili e forniamo una caratterizzazione formale dell'entanglement multipartito. Ciò ci richiede di lavorare con un formalismo astratto che può essere utilizzato per definire l'entanglement nei sistemi quantistici a molti corpi senza fare riferimento a una struttura specifica degli stati. Per mostrare ulteriormente questa tecnica, e anche motivata dagli attuali sforzi di simulazione quantistica, la usiamo per estendere la struttura dei testimoni di entanglement alle teorie di gauge del reticolo.

Settore FIS/03 - Fisica della Materia

The black hole information paradox and holography

Mola Bertran, Ona

January 2023

Hawking theorized in 1974 that black holes emit particles as a quantum effect. It follows from this fact that a black hole that emits particles while absorbing none ends up evaporating. The process of black hole evaporation studied from semiclassical gravity violates quantum mechanics leading to serious problems. This is the black hole information paradox, one of the most famous paradoxes in theoretical physics first pointed out by Hawking in 1975 and still unsolved today. Nowadays the widespread interpretation is that quantum mechanics cannot be violated and that the semiclassical gravity approach is not good enough. We need to go beyond semiclassical physics to understand this process. The paradox as originally stated by Hawking is that a pure state evolves into a mixed state, violating unitarity and losing information in the process. There is also an alternative way to state the paradox using the so-called Page curve, which involves working with entropies rather than states. In a unitary process, the entanglement entropy of the radiation will follow the Page curve. In 2019, it was shown explicitly using holographic tools that an evaporating black hole in an Anti-de Sitter spacetime follows the Page curve. Holography is a property of quantum gravity stating that a spatial region can be described by its area rather than its volume. These recent developments also involve the famous island rule as the formula that reproduces the Page curve. This master thesis reviews the current understanding of the paradox, exploring the original paradox as well as the recent developments in the field.

information paradox

semiclassical physics

holography

AdS/CFT correspondence

island formula

entanglement entropy

Astronomy, Astrophysics and Cosmology

Astronomi, astrofysik och kosmologi