Global ETD Search

121	Mesure de la Viscosité dans l'Hélium 3 liquide fortement polarisé BUU, Olivier 16 December 1998 (has links) (PDF) L'3He à basse température est l'archétype d'un fluide de fermions en interaction. Le but de cette thèse est d'étudier expérimentalement un effet quantique dans l'3He liquide~: L'influence de la polarisation nucléaire sur la viscosité. Ce type d'effet est connu dans la phase gazeuse, mais les modèles théoriques donnent des réponses diverses concernant la phase liquide. Expérimentalement, la difficulté consiste à obtenir de forts taux de polarisation dans l'3He liquide. Nous utilisons pour cela la méthode de fusion rapide d'un solide aimanté. La viscosité étant une quantité fortement dépendante de la température, il faut un bon contrôle de l'homogénéité thermique dans la cellule expérimentale pour isoler les effets dus à la polarisation des variations de température liées à la méthode de fusion rapide. En accord avec des mesures antérieures, nous montrons que la polarisation nucléaire a pour effet d'augmenter la viscosité. Grâce à un dispositif expérimental de conception soignée, nous étendons la gamme de polarisation explorée jusqu'à des taux de 60\%. De plus, des expériences à différentes températures nous permettent de montrer que cet effet survit au-delà du régime où les spins sont dégénérés, et disparaît vers 1K. Enfin, nous montrons que l'effet de la polarisation dépend peu de la pression. Ces résultats posent des questions théoriques importantes dans les deux régimes de température que nous avons explorés~: Il faut raffiner les modèles existants pour comprendre la faible dépendance en pression de l'effet de la polarisation sur la viscosité à basse température. A haute température, il s'agit de comprendre comment des effets de statistique quantique peuvent subsister en-dehors du régime dégénéré dans un système dense. [PHYS:COND] Physics/Condensed Matter Basses températures Fermions corrélés Principe de Pauli Hélium polarisation nucléaire viscosité
122	Phase transitions in high-temperature superconductors Lidmar, Jack January 1998 (has links) Thermal fluctuations and disorder strongly influence the behaviour of hightemperature superconductors. In particular the vortices play a key role in determining their properties. In this thesis the main focus lies on phase transitions, both in ultra-thin films and in three-dimensional systems, which are driven by vortex fluctuations. The last paper concerns the influence of antiferromagnetism on superconductivity in a simple model. A brief review of these topics is given in the introductory part. The main results are: The phase transition in ultra-thin superconducting/superfluid films is studied within the two-dimensional Coulomb gas model, which is known to have a Berezinskii-Kosterlitz-Thouless transition at low vortex densities. We construct the phase diagram from grand canonical Monte Carlo simulations on a continuum, without any restrictions on the vortex density. The dynamical universality classes for vortices in superconductors in zero magnetic field are studied by means of Monte Carlo simulations, with particular attention to the role of screening of the vortex interaction. We construct a formula for the k = 0 helicity modulus directly in terms of the vortex line fluctuations, which can serve as a useful way to detect superconducting coherence in model calculations. A method for simulating vortex lines on a continuum is developed, and used to study the melting of the Abrikosov vortex lattice. We study the critical dynamics for vortices in the presence of columnar defects. The linear resistivity and current-voltage characteristics are calculated in Monte Carlo simulations, and the critical behaviour extracted using finite size scaling. We reconsider the scaling properties as the magnetic field is tilted away from the direction of the columns. The influence of antiferromagnetic correlations on the superconducting properties is studied in a simplified lattice fermion model for superconductivity in the presence of an antiferromagnetic background. We find that the superconducting critical temperature is enhanced by antiferromagnetic order, and that a gap with dx2-y2-wave symmetry is the most stable. / QC 20100512 Superconductivity Vortices Phase transitions Strongly correlated fermions High-temperature superconductivity Monte Carlo simulations. TECHNOLOGY TEKNIKVETENSKAP
123	Probing Exotic Boundary Quantum Phases with Tunable Nanostructure Liu, Dong January 2012 (has links) <p>Boundary quantum phases ---a special type of quantum phenomena--- occur in the boundary part of the system. The boundary part can be a surface of a bulk material, an interface between two distinct system, and even it can be a single impurity or a impurity cluster embedded into a bulk system. The properties of the boundary degree of freedom can be affected by many strong electron correlation effects, mesoscopic effects, and topological effects, which, therefore, induce a vast variety of exotic boundary quantum phases. Many techniques for precise fabrication and measurement in nanostructures had been developed,</p><p>which can provide ways to prob, understand, and control those boundary quantum phases.</p><p>In this thesis, we focus on three types of the boundary quantum phases : Kondo effects, boundary quantum phase transitions, and Majorana fermions. Our motivation is to design and prob those effects by using a important type of nanostructures, i.e. quantum dots. A vast variety of models related to quantum dots (QDs) are studied theoretically, which includes a QD coupled to a mesoscopic bath, a quadruple QD system with metallic leads, a QD with dissipative environments, and a QD coupled to a Majorana fermion zero mode.</p><p>Quantum dots provide a way to study the interplay of Kondo effects and mesoscopic fuctuations. In chapter 5, we consider a model including an Anderson impurity (small QD) coupled to a mesoscopic bath (large QD). Both the weak and strong coupling Anderson impurity problems are characterized by Fermi-liquid theories with weakly interacting quasiparticles. We find that the fluctuations of single particle properties in the two limits are highly correlated and universal : The distributions of the spectrum within the Kondo temperature collapse to universal forms; and the strong coupling impurity changes the wave functions corresponding to the spectrum within the Kondo temperature. </p><p>Quantum dots also bring the possibility to study more complex quantum impurities (multi-QDs) and the competition among dierent interactions, which may induce exotic effects: boundary quantum phase transitions and novel Kondo effects. In chapter 7, we design a quadruple quantum dot system to study the competition among three types of interactions: Kondo, Heisenberg, and Ising. We find a rich phase diagram containing two sharp features : a Berezinsky-Kosterlitz-Thouless type quantum phase transition between a charge-ordered phase and a charge liquid phase and a U(1)XU(1) Kondo state with emergent symmetry from Z2 to U(1). In chapter 8, we study a dissipative resonant level model in which the coupling of a fermionc bath competes with a dissipation-induced bosonic bath. we establish an exact mapping from this dissipative resonant level model to a model of a quantum dot embedded into a Luttinger liquid wire, and we also find two kinds of boundary quantum phase transitions (a Berezinsky-Kosterlitz-Thouless type and a second order type).</p><p>Finally, in chapter 9, we propose an experimental system to detect Majorana fermion zero modes. This system consists of a spinless quantum do coupled to a Majorana fermion which exists in the end of a p-wave superconductor wire. The Majorana Fermion strongly infuence the transport properties of the quantum dot. The zero temperature conductance peak value (when the dot is on resonance and symmetrically coupled to the leads) is e^2/2h. In contrast, if the wire is in its topological trivial phase, the result is e^2/h; if the side-coupled mode is a regular fermionic zero mode, the result is zero. Driving the wire through the topological phase transition causes a sharp jump in the conductance by a factor of 1/2. This result can be used to detect the existence of Majorana fermions.</p> / Dissertation Theoretical physics Nanoscience Boundary quantum phases Kondo effects Majorana fermions Quantum dots quantum phase transitions
124	Quantum Monte Carlo Methods For Fermionic Systems: Beyond The Fixed-node Approximation Dugan, Nazim 01 August 2010 (has links) (PDF) Developments are made on the quantum Monte Carlo methods towards increasing the precision and the stability of the non fixed-node projector calculations of fermions. In the first part of the developments, the wavefunction correction scheme, which was developed to increase the precision of the diusion Monte Carlo (DMC) method, is applied to non fixed-node DMC to increase the precision of such fermion calculations which do not have nodal error. The benchmark calculations indicate a significant decrease of statistical error due to the usage of the correction scheme in such non fixed-node calculations. The second part of the developments is about the modifications of the wavefunction correction scheme for having a stable non fixed-node DMC algorithm for fermions. The minus signed walkers of the non fixed-node calculations are avoided by these modifications in the developed stable algorithm. However, the accuracy of the method decreases, especially for larger systems, as a result of the discussed modifications to overcome the sign instability.
125	Electrons corrélés sous haute pression: Une approche par diffusion inélastique des rayons X Rueff, Jean-Pascal 27 June 2007 (has links) (PDF) Ce travail de revue traite des propriétés électroniques des systèmes à électrons fortement corrélés sous haute pression par diffusion inélastique résonante des rayons X (RIXS). Les principaux phénomènes induits sous pression sont présentés dans l'introduction ainsi que les bases de la diffusion RIXS. Le corps principal du manuscrit décrit les résultats obtenus dans les métaux 3d - transitions magnétiques - et 4f - fluctuations de valence. [PHYS:COND] Physics/Condensed Matter Electrons fortement corrélés fermions lourds haute pression diffusion inélastique rayons X
126	Etude microscopique de systèmes fermioniques finis corrélations dans les noyaux atomiques et gaz d'électrons confinés par un potentiel harmonique en présence d'un champ magnétique / Naïdja, Houda Quentin, Philippe Bencheikh, Kamel January 2009 (has links) (PDF) Thèse de doctorat : Sciences physiques et de l'ingénieur. Physique nucléaire : Bordeaux 1 : 2009. Thèse de doctorat : Sciences physiques et de l'ingénieur. Physique nucléaire : Université Ferhat Abbas, Sétif, Algérie : 2009. / Titre provenant de l'écran-titre.
127	Quantum cosmological correlations in inflating universe: effect of gravitational fluctuation due to fermion, gauge, and others [sic] loops Chaicherdsakul, Kanokkuan 28 August 2008 (has links) Not available Inflationary universe Fluctuations (Physics) Fermions Gauge fields (Physics) Scalar field theory Gravitation Cosmic background radiation
128	Topological Properties of Interacting Fermionic Systems Dos Santos, Luiz Henrique Bravo 17 December 2012 (has links) This thesis is a study of three categories of problems in fermionic systems for which topology plays an important role: (i) The properties of zero modes arising in systems of fermions interacting with a bosonic background, with a special focus on Majorana modes arising in the superconductor state. We propose a method for counting Majorana modes and we study a mechanism for controlling their number parity in lattice systems, two questions that are of relevance to the protection of quantum bits. (ii) The study of dispersionless bands in two dimensions as a platform for correlated physics, where it is shown the possibility of stabilizing the fractional quantum Hall effect in a flat band with Chern number. (iii) The extension of the hierarchy of quantum Hall fluids to the case of time-reversal symmetric incompressible ground states describing a phase of strongly interacting topological insulators in two dimensions. / Physics Chern number Majorana fermions physics condensed matter physics flat bands quantum Hall effect topology topological insulators
129	États de bord dans les isolants de Chern et les fermions de Majorana dans les supraconducteurs topologiques Sticlet, Doru Cristian 27 November 2012 (has links) (PDF) Cette thèse poursuit deux directions dans le domaine des isolants et supraconducteurs topologiques.Dans la première partie de la thèse nous étudions des isolants en deux dimensions sur réseau, présentant un effet Hall quantique anormal (c'est-à-dire en l'absence d'un champ magnétique externe), induit par la présence d'un flux magnétique inhomogène dans la maille. Le système possède des phase isolantes caractérisés par un invariant topologique, le nombre de Chern, qui est lié à la conductance portée par le bord états. Nous montrons que les modèles à deux bandes admettent des phase à nombre de Chern arbitraire, ou, de façon équivalente, un nombre arbitraire d'états de bord, quand on augmente la portée des couplages sur réseau. Cette compréhension est rendue possible grâce à la démonstration d'une formule montrant que le nombre de Chern d'une bande dépend de certains propriétés d'un ensemble discret de points dans la zone de Brillouin, les points de Dirac en l'absence du gap. Ces idées sont rendues plus concrètes dans l'étude du modèle de Haldane et dans la création d'un modèle artificiel avec cinq phases de Chern dont les états de bord sont déterminés en détail. La deuxième partie de la thèse porte sur les supraconducteurs topologiques unidimensionnels qui exhibent des états exotiques d'énergie zéro: les états liés de Majorana. Nous étudions ici la présence de fermions de Majorana dans des fils de semiconducteurs à fort couplage spin-orbite sous l'effet de proximité d'un supraconducteur d'onde s. Nous montrons que la polarisation de spin des degrés de liberté électroniques dans la fonction d'onde Majorana dépend du poids relatif du couplage spin-orbite Dresselhaus et Rashba. Nous étudions également les fermions de Majorana dans des jonctions linéaires longues supraconducteur-normal et supraconducteur-normal-supraconducteur (SNS) où ils apparaissent comme des états étendus dans la jonction normale. En outre, la géométrie d'anneaux peut être mise en correspondance avec une jonction SNS, et, sous l'action de gradients dans la phase supraconductrice, des fermions Majorana étendus se forment encore à l'intérieur du fil normal. Enfin, un modèle à deux bandes avec des fermions de Majorana multiples est traité. Nous démontrons que les jonctions Josephson construites à partir de ce modèle maintiennent l'une des signatures remarquables des fermions de Majorana, à savoir la périodicité 4π de l'effet Josephson fractionnaire. Isolants topologiques Points de Dirac Fermions de Majorana Effet Josephson
130	Controlling the Properties of 2D Chiral Fermions and Local Moments in Graphene Killi, Matthew P. 08 August 2013 (has links) The primary subject of this thesis is graphene and how the rudimentary attributes of its charge carriers, and local moments on its surface, can be directly manipulated and controlled with electrostatic potentials. We first consider bilayer graphene subject to a spatially varying electrostatic potential that forms two neighbouring regions with opposite interlayer bias. Along the boundary, 1D chiral `kink' states emerge. We find that these 1D modes behave as a strongly interacting Tomonaga-Luttinger liquid whose properties can be tuned via an external gate. Next, we consider superlattices in bilayer graphene. Superlattices are seen to have a more dramatic effect on bilayer graphene than monolayer graphene because the quasiparticles are changed in a fundamental way; the dispersion goes from a quadratic band touching point to linearly dispersing Dirac cones. We illustrate that a 1D superlattice of either the chemical potential or an interlayer bias generates multiple anisotropic Dirac cones. General arguments delineate how certain symmetries protect the Dirac points. We then map the Hamiltonian of an interlayer bias superlattice onto a coupled chain model comprised of `topological' edge modes. We then discuss the relevance of spatially varying potentials to recent transport measurements. This is followed by another study that considers the effect of a magnetic field on graphene superlattices. We show that magnetotransport measurements in a weak perpendicular (orbital) magnetic field probe the number of emergent Dirac points and reveal further details about the dispersion. In the case of bilayer graphene, we also discuss the properties of kink states in an applied magnetic field. We then consider the implications of these results with regards to scanning tunnelling spectroscopy, valley filtering, and impurity induced breakdown of the quantum Hall effect. Finally, we investigate local moment formation of adatoms on bilayer graphene using an Anderson impurity model. We construct various phase diagrams and discuss their many unusual features. We identify regions where the local moments can be turned on or off by applying a external electric fields. Finally, we compute the RKKY interaction between local moments and show how it too can be controlled with electric fields. graphene physics dirac fermions topological quantum hall local moments bilayer graphene Luttinger Liquid 0611

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