Global ETD Search

1	Conductivity behavior of LaNiO3- and LaMnO3- based thin film superlattices Wei, Haoming 09 May 2017 (has links) (PDF) The present work covers the fabrication and electrical and magnetic investigation of LaNiO3- and LaMnO3- based superlattices (SL). In recent years, several interesting theoretical predictions have been made in these SLs, for example, Mott insulators, metal-insulator transitions, superconductivity, topological insulators, and Chern insulators. Motivated by the promising theoretical predictions, four kinds of SLs with different designed structures and orientations were systematically studied in this thesis. The samples were grown by pulsed laser deposition with in-situ reflection high-energy electron diffraction to monitor the two-dimensional layer-by-layer growth process. In order to ensure the high-quality of SLs, growth parameters were optimised. Characteristic methods like X-ray diffraction, atomic force microscopy, and transmission electron microscopy were used. These measurements proved the high-quality of the SLs and provided the basis for electrical and magnetic measurements. The first studied SL is the (001)-oriented LaNiO3/LaAlO3 SL, which was predicted as a superconductor in theory. Temperature-dependent resistivity measurements revealed a metal-insulator transition by lowering the dimensionality of the LaNiO3 layers in the SLs from three dimensions to two dimensions. The second studied SL is the (111)-oriented LaNiO3/LaAlO3 SL, which was predicted as a topological insulator in theory. The polarity-controlled conductivity was observed and the intrinsic conductivity mechanisms were discussed by means of appropriate modeling. The third studied SL is LaMnO3/LaAlO3 SL, which was predicted as a Chern insulator in theory. By lowering the temperature, a paramagnetic-ferromagnetic phase transition and a thermal activated behavior were observed in the SLs. The last studied SL is the LaNiO3/LaMnO3 SL, in which an exchange bias effect was expected. The studies reveal the exchange bias exists in three kinds of SLs with different orientations. Übergitter Supraleitung Topologische Isolatoren superlattices chern insulator superconductivity exchange bias effect ddc:530
2	Numerical study of fractional topological insulators / Etude numérique des isolants topologiques fractionnaires Repellin, Cécile 25 September 2015 (has links) Les isolants topologiques sont des isolants qui ne peuvent être différenciés des isolants atomiques que par une grandeur physique non locale appelée invariant topologique. L'effet Hall quantique et son équivalent sans champ magnétique l'isolant de Chern sont des exemples d'isolants topologiques. En présence d'interactions fortes, des excitations exotiques appelées anyons peuvent apparaître dans les isolants topologiques. L'effet Hall quantique fractionnaire (EHQF) est la seule réalisation expérimentale connue de ces phases. Dans ce manuscrit, nous étudions numériquement les conditions d'émergence de différents isolants topologiques fractionnaires. Nous nous concentrons d'abord sur l'étude de l'EHQF sur le tore. Nous introduisons une méthode de construction projective des états EHQF les plus exotiques complémentaire par rapport aux méthodes existantes. Nous étudions les excitations de basse énergie sur le tore de deux états EHQF, les états de Laughlin et de Moore-Read. Nous proposons des fonctions d'onde pour les décrire, et vérifions leur validité numériquement. Grâce à cette description, nous caractérisons les excitations de basse énergie de l'état de Laughlin dans les isolants de Chern. Nous démontrons également la stabilité d'autres états de l'EHQF dans les isolants de Chern, tels que les états de fermions composites, Halperin et NASS. Nous explorons ensuite des phases fractionnaires sans équivallent dans la physique de l'EHQF, d'abord en choisissant un modèle dont l'invariant topologique a une valeur plus élevée, puis en imposant au système la conservation de la symétrie par renversement du temps, ce qui modifie la nature de l'invariant topologique. / Topological insulators are band insulators which are fundamentally different from atomic insulators. Only a non-local quantity called topological invariant can distinguish these two phases. The quantum Hall effect is the first example of a topological insulator, but the same phase can arise in the absence of a magnetic field, and is called a Chern insulator. In the presence of strong interactions, topological insulators may host exotic excitations called anyons. The fractional quantum Hall effect is the only experimentally realized example of such phase. In this manuscript, we study the conditions of emergence of different types of fractional topological insulators, using numerical simulations. We first look at the fractional quantum Hall effect on the torus. We introduce a new projective construction of exotic quantum Hall states that complements the existing construction. We study the low energy excitations on the torus of two of the most emblematic quantum Hall states, the Laughlin and Moore-Read states. We propose and validate model wave functions to describe them. We apply this knowledge to characterize the excitations of the Laughlin state in Chern insulators. We show the stability of other fractional quantum Hall states in Chern insulators, the composite fermion, Halperin and NASS states. We explore the physics of fractional phases with no equivalent in a quantum Hall system, using two different strategies: first by choosing a model with a higher value of the topological invariant, second by adding time-reversal symmetry, which changes the nature of the topological invariant. Effet Hall quantique Isolant topologique Isolant de Chern Anyon Fractionalisation Quantum Hall effect Topological insulator Chern insulator Fractionalization 530
3	Conductivity behavior of LaNiO3- and LaMnO3- based thin film superlattices Wei, Haoming 24 April 2017 (has links) The present work covers the fabrication and electrical and magnetic investigation of LaNiO3- and LaMnO3- based superlattices (SL). In recent years, several interesting theoretical predictions have been made in these SLs, for example, Mott insulators, metal-insulator transitions, superconductivity, topological insulators, and Chern insulators. Motivated by the promising theoretical predictions, four kinds of SLs with different designed structures and orientations were systematically studied in this thesis. The samples were grown by pulsed laser deposition with in-situ reflection high-energy electron diffraction to monitor the two-dimensional layer-by-layer growth process. In order to ensure the high-quality of SLs, growth parameters were optimised. Characteristic methods like X-ray diffraction, atomic force microscopy, and transmission electron microscopy were used. These measurements proved the high-quality of the SLs and provided the basis for electrical and magnetic measurements. The first studied SL is the (001)-oriented LaNiO3/LaAlO3 SL, which was predicted as a superconductor in theory. Temperature-dependent resistivity measurements revealed a metal-insulator transition by lowering the dimensionality of the LaNiO3 layers in the SLs from three dimensions to two dimensions. The second studied SL is the (111)-oriented LaNiO3/LaAlO3 SL, which was predicted as a topological insulator in theory. The polarity-controlled conductivity was observed and the intrinsic conductivity mechanisms were discussed by means of appropriate modeling. The third studied SL is LaMnO3/LaAlO3 SL, which was predicted as a Chern insulator in theory. By lowering the temperature, a paramagnetic-ferromagnetic phase transition and a thermal activated behavior were observed in the SLs. The last studied SL is the LaNiO3/LaMnO3 SL, in which an exchange bias effect was expected. The studies reveal the exchange bias exists in three kinds of SLs with different orientations. info:eu-repo/classification/ddc/530 ddc:530
4	Topology Meets Frustration : Exact Solutions for Topological Surface States on Geometrically Frustrated Lattices Kunst, Flore Kiki January 2017 (has links) One of the main features of topological phases is the presence of robust boundary states that are protected by a topological invariant. Famous examples of such states are the chiral edge states of a Chern insulator, the helical edge states of a two-dimensional Z2 insulator, and the Fermi arcs of Weyl semimetals. Despite their omnipresence, these topological boundary states can typically only be theoretically investigated through numerical studies due to the lack of analytical solutions for their wave functions. In the rare cases that wave-function solutions are available, they only exist for simple fine-tuned systems or for semi-infinite systems. Exact solutions are, however, common in the field of flat bands physics, where they lead to an understanding of the bulk bands rather than the boundary physics. It is well known that fully-periodic lattices with a frustrated geometry host localized modes that have a constant energy throughout the Brillouin zone. These localized modes appear due to a mechanism referred to as destructive interference, which leads to the disappearance of the wave-function amplitude on certain lattice sites. Making use of this mechanism, it is shown in this licentiate thesis that exact wave-function solutions can also be found on d-dimensional geometrically frustrated lattices that feature (d − 1)-dimensional boundaries. These exact solutions localize to the boundaries when the frustrated lattice hosts a topological phase and correspond to the robust, topological boundary states. This licentiate thesis revolves around the publication, which describes the method to finding these exact, analytical solutions for the topological boundary states on geometrically frustrated lattices, which was authored by the author of this licentiate thesis together with Maximilian Trescher and Emil J. Bergholtz and published in Physical Review B on August 30, 2017 with the title Anatomy of topological surface states: Exact solutions from destructive interference on frustrated lattices. An introduction is given on topological phases in condensed matter systems focussing on those models of which explicit examples are given in the paper: two-dimensional Chern insulators and three-dimensional Weyl semimetals. Moreover, by making use of the kagome lattice as an example the appearance of localized and semi-localized modes on geometrically frustrated lattices is elaborated upon. The chapters in this licentiate thesis thus endeavor to provide the reader with the proper background to comfortably read, understand, place into context and judge the relevance of the work in the accompanying publication. The licentiate thesis finishes with an outlook where it is discussed that the method presented in the paper can be generalized to an even larger class of lattices and can also be applied to find exact solutions for higher-order topological phases such as corner and hinge states. Topology boundary states surface states edge states Chern insulator Weyl semimetal Condensed Matter Physics Den kondenserade materiens fysik
5	Characterization of topological phases in models of interacting fermions Motruk, Johannes 15 July 2016 (has links) (PDF) The concept of topology in condensed matter physics has led to the discovery of rich and exotic physics in recent years. Especially when strong correlations are included, phenomenons such as fractionalization and anyonic particle statistics can arise. In this thesis, we study several systems hosting topological phases of interacting fermions. In the first part, we consider one-dimensional systems of parafermions, which are generalizations of Majorana fermions, in the presence of a Z_N charge symmetry. We classify the symmetry-protected topological (SPT) phases that can occur in these systems using the projective representations of the symmetries and find a finite number of distinct phases depending on the prime factorization of N. The different phases exhibit characteristic degeneracies in their entanglement spectrum (ES). Apart from these SPT phases, we report the occurrence of parafermion condensate phases for certain values of N. When including an additional Z_N symmetry, we find a non-Abelian group structure under the addition of phases. In the second part of the thesis, we focus on two-dimensional lattice models of spinless fermions. First, we demonstrate the detection of a fractional Chern insulator (FCI) phase in the Haldane honeycomb model on an infinite cylinder by means of the density-matrix renormalization group (DMRG). We report the calculation of several quantities characterizing the topological order of the state, i.e., (i)~the Hall conductivity, (ii)~the spectral flow and level counting in the ES, (iii)~the topological entanglement entropy, and (iv)~the charge and topological spin of the quasiparticles. Since we have access to sufficiently large system sizes without band projection with DMRG, we are in addition able to investigate the transition from a metal to the FCI at small interactions which we find to be of first order. In a further study, we consider a time-reversal symmetric model on the honeycomb lattice where a Chern insulator (CI) induced by next-nearest neighbor interactions has been predicted by mean field theory. However, various subsequent studies challenged this picture and it was still unclear whether the CI would survive quantum fluctuations. We therefore map out the phase diagram of the model as a function of the interactions on an infinite cylinder with DMRG and find evidence for the absence of the CI phase. However, we report the detection of two novel charge-ordered phases and corroborate the existence of the remaining phases that had been predicted in mean field theory. Furthermore, we characterize the transitions between the various phases by studying the behavior of correlation length and entanglement entropy at the phase boundaries. Finally, we develop an improvement to the DMRG algorithm for fermionic lattice models on cylinders. By using a real space representation in the direction along the cylinder and a real space representation in the perpendicular direction, we are able to use the momentum around the cylinder as conserved quantity to reduce computational costs. We benchmark the method by studying the interacting Hofstadter model and report a considerable speedup in computation time and a severely reduced memory usage. Topologische Ordnung symmetriegeschützte topologische Phasen Parafermionen fraktionaler Chernisolator Dichtematrixrenormierungsgruppe Topological order symmetry-protected topological phases parafermions fractional Chern insulator density matrix renormalization group ddc:530 rvk:UP 4600
6	Transport électronique dans le graphène et les isolants topologiques 2D en présence de désordre magnétique / Electronic transport in graphene and 2D topological insulators with magnetic disorder Demion, Arnaud 06 November 2015 (has links) Dans cette thèse, nous étudions l’effet du désordre magnétique sur les propriétés de transport électronique du graphène et des isolants topologiques 2D de type HgTe. Le graphène et les isolants topologiques sont des matériaux dont les excitations électroniques sont assimilées à des fermions de Dirac sans masse. L’influence des impuretés magnétiques sur les propriétés de transport du graphène est étudiée dans le régime de forts champs électriques. En conséquence de la production de paires électron-trou, la réponse devient non linéaire et dépend de la polarisation magnétique. Nous étudions une transition entre un isolant topologique bi-dimensionnel conducteur, caractérisé par une conductance G = 2 (en quantum de conductance) et un isolant de Chern avec G = 1, induite par des impuretés magnétiques polarisées. / In this thesis, we study the effect of a magnetic disorder on the electronic transport properties of graphene and HgTe-type 2D topological insulators. Graphene and topological insulators are materials whose electronic excitations are treated as massless Dirac fermions.The influence of magnetic impurities on the transport properties of graphene is investigated in the regime of strong applied electric fields. As a result of electron-hole pair creation, the response becomes nonlinear and dependent on the magnetic polarization.We investigate a transition between a two-dimensional topological insulator conduction state, characterized by a conductance G = 2 (in conductance quantum) and a Chern insulator with G = 1, induced by polarized magnetic impurities. Isolant topologique Graphène Désordre magnétique Localisation Fermion de Dirac Isolant de Chern Transition de phase quantique Topological insulator Graphene Magnetic disorder Localization Dirac fermion Chern insulator Quantum phase transition
7	Characterization of topological phases in models of interacting fermions Motruk, Johannes 25 May 2016 (has links) The concept of topology in condensed matter physics has led to the discovery of rich and exotic physics in recent years. Especially when strong correlations are included, phenomenons such as fractionalization and anyonic particle statistics can arise. In this thesis, we study several systems hosting topological phases of interacting fermions. In the first part, we consider one-dimensional systems of parafermions, which are generalizations of Majorana fermions, in the presence of a Z_N charge symmetry. We classify the symmetry-protected topological (SPT) phases that can occur in these systems using the projective representations of the symmetries and find a finite number of distinct phases depending on the prime factorization of N. The different phases exhibit characteristic degeneracies in their entanglement spectrum (ES). Apart from these SPT phases, we report the occurrence of parafermion condensate phases for certain values of N. When including an additional Z_N symmetry, we find a non-Abelian group structure under the addition of phases. In the second part of the thesis, we focus on two-dimensional lattice models of spinless fermions. First, we demonstrate the detection of a fractional Chern insulator (FCI) phase in the Haldane honeycomb model on an infinite cylinder by means of the density-matrix renormalization group (DMRG). We report the calculation of several quantities characterizing the topological order of the state, i.e., (i)~the Hall conductivity, (ii)~the spectral flow and level counting in the ES, (iii)~the topological entanglement entropy, and (iv)~the charge and topological spin of the quasiparticles. Since we have access to sufficiently large system sizes without band projection with DMRG, we are in addition able to investigate the transition from a metal to the FCI at small interactions which we find to be of first order. In a further study, we consider a time-reversal symmetric model on the honeycomb lattice where a Chern insulator (CI) induced by next-nearest neighbor interactions has been predicted by mean field theory. However, various subsequent studies challenged this picture and it was still unclear whether the CI would survive quantum fluctuations. We therefore map out the phase diagram of the model as a function of the interactions on an infinite cylinder with DMRG and find evidence for the absence of the CI phase. However, we report the detection of two novel charge-ordered phases and corroborate the existence of the remaining phases that had been predicted in mean field theory. Furthermore, we characterize the transitions between the various phases by studying the behavior of correlation length and entanglement entropy at the phase boundaries. Finally, we develop an improvement to the DMRG algorithm for fermionic lattice models on cylinders. By using a real space representation in the direction along the cylinder and a real space representation in the perpendicular direction, we are able to use the momentum around the cylinder as conserved quantity to reduce computational costs. We benchmark the method by studying the interacting Hofstadter model and report a considerable speedup in computation time and a severely reduced memory usage. info:eu-repo/classification/ddc/530 ddc:530
8	INTERPLAY OF GEOMETRY WITH IMPURITIES AND DEFECTS IN TOPOLOGICAL STATES OF MATTER Guodong Jiang (10703055) 27 April 2021 (has links) The discovery of topological quantum states of matter has required physicists to look beyond Landau’s theory of symmetry-breaking, previously the main paradigm for<br>studying states of matter. This has led also to the development of new topological theories for describing the novel properties. In this dissertation an investigation in this<br>frontier research area is presented, which looks at the interplay between the quantum geometry of these states, defects and disorder. After a brief introduction to the topological quantum states of matter considered herein, some aspects of my work in this area are described. First, the disorder-induced band structure engineering of topological insulator surface states is considered, which is possible due to their resilience from Anderson localization, and believed to be a consequence of their topological origin.<br>Next, the idiosyncratic behavior of these same surface states is considered, as observed in experiments on thin film topological insulators, in response to competition between<br>hybridization effects and an in-plane magnetic field. Then moving in a very different direction, the uncovering of topological ‘gravitational’ response is explained: the<br>topologically-protected charge response of two dimensional gapped electronic topological states to a special kind of 0-dimensional boundary – a disclination – that encodes spatial curvature. Finally, an intriguing relation between the gravitational response of quantum Hall states, and their response to an apparently unrelated perturbation – nonuniform electric fields is reported. <br> Computational Physics Condensed Matter Physics Quantum Mechanics General Relativity Topological quantum phases spatial curvature topological invariant topological gravitational response gauge-invariant variable quantum Hall topological insulator Chern insulator Dirac fermion impurity topological defect disclination T matrix Green's function disorder

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