DOCSLIB.ORG

Constraints on Topological Defect Formation in First-Order

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

Constraints on Topological Defect Formation in First-order Superconducting Phase Transitions J. P´aramos Instituto Superior T´ecnico, Departamento de F´ısica, Av. Rovisco Pais 1, 1049-001 Lisboa, Portugal E-mail address: x [email protected] In this work we address the impact of a cubic term addition to the Ginzburg-Landau mean- field potential, and study the consequences on the description of first order phase transitions in superconductors. Constraints are obtained from experiment and used to assess consequences on topological defect creation. No fundamental changes in either the Kibble-Zurek or Hindmarsh- Rajantie predictions are found. I. INTRODUCTION which are known as flux tubes or vortices, lines of non- null magnetic field trapped inside the superconductor. Experiments targeted at observing defect densities in The following work is based on the research reported in high-T materials [10] were not in accordance with the Ref. [1]. It pursues the objective of empathizing the anal- c density predictions of the Kibble-Zurek (K-Z) mecha- ogy between accessible condensed matter systems and the nism [2]. This, however, is to be expected, since the currently accepted framework for the evolution of the K-Z prediction should be accurate only for global gauge Universe, notably the symmetry-breaking phase transi- symmetry breaking, when the geodesic rule for phase an- tions [2, 3] it has undergone after the Big-Bang. A key as- gle summation is valid. A new defect generation mech- pect to this comparison is the creation of topological de- anism, based on a local gauge treatment by Hindmarsh fects, frustrations of the unbroken phase within the bro- and Rajantie (H-R) [11], leads to an (additive) predic- ken one, arising from the continuity of the order param- tion. This, although well below the first Carmi-Polturak eter values. These are generally categorized according experimental sensitivity, is in reasonable agreement with to the homotopy group of the quocient of the unbroken the second. symmetry groups to the broken one and which enables for comparison of different physical phenomena. These As a starting point for this research, we note that the objects can appear as magnetic monopoles or point-like above experiments were both conducted in type-II ma- defects, cosmic strings, vortices or flux tubes, magnetic terials, which exhibit a higher critical temperature and domain walls or textures. Besides its mere aesthetical are therefore easier to manipulate, leading the current value, this analogy can provide a powerful probe into the trend in experimental superconductivity. These materi- early stages of the evolution of the Universe, since direct, als display a second order phase transition, with no re- hands-on experimental tests are unattainable: the exis- lease of latent heat. On the other hand, Type-I materials tence of more accessible systems that exhibit a formally are metastable, showing different responses to a magnetic similar behavior could provide crucial clues to many cos- field when in normal-superconductor or superconductor- mologically relevant issues. normal phase transitions. In this work, we try to account These “cosmology in the laboratory” experiments can for this more elaborate behavior and to estimate to which arXiv:hep-ph/0403011v2 27 Apr 2004 be found in various systems, ranging from vortices in extent it affects the defect density predictions for type-I superfluid phase transitions of 4He and 3He (see e.g. superconductors. Ref. [4, 5]), which exhibit common features with cos- Type-I and type-II superconductors are commonly dis- mic strings [6], to liquid crystals undergoing an isotropic- tinguished according to their Ginzburg-Landau (G-L) pa- nematic phase transition [7, 8]. Polymer chains were rameter κ = λ/ξ, the ratio between the magnetic field shown to also possess analogous thermodynamic and penetration length λ and the coherence length ξ of the transitional behavior [9]. However, most of these sys- order parameter. In the presence of a gauge field A~, these tems lack the existence of a quantity analogous to the characteristic length scales are obtained from the free en- magnetic field, which could be a key player in the early ergy density evolution of the Universe and formation of structure. For that reason, superconductors are a case of special in- terest. These comprise phase transitions involving a lo- 1 e 2 1 cal gauge symmetry-breaking process, during which the F (Φ) = i¯h~ Φ A~Φ + V (Φ) + ~µ (~ A~) , photon acquires a “mass” and, therefore, a penetration 2me ∇ − c 2 · ∇× length, giving rise to the Meissner effect: the expulsion of (1) the magnetic field from a superconducting material, with where ~µ is the sample’s magnetic moment, me is the elec- formation of shielding “supercurrents” on its surface. tron mass and Φ is the order parameter. The G-L po- This symmetry breaking originates topological defects tential is usually written as [6] 667 In the normal-to-superconductor phase transition, a term similar to γ Φ 3 also arises if one takes into ac- count gauge field− fluctuations| | [13, 14], producing e γ =8µ √πµ T . (6) 0 ¯hc 0 c This result enables a first order phase transition for all values of κ. Thermal fluctuations [14] and non local BCS effects [15] describe crossover behavior between first and second order transitions. FIG. 1: Characteristic Potential curves. In the following, we adopt a potential of the form of Eq. (5) and constrain γ(T ) based on experimental data. The results are then compared with both TFT 1-loop radia- tive corrections and the the results of Ref. [13] (valid only β at temperature close to T , that is, t 1). The intro- V (Φ) = αΦ2 + Φ4 , (2) c → 2 duction of γ(T ) in the potential (2) can produce changes in both the K-Z and H-R defect generating mechanisms. where α is assumed to be linear with temperature, α = Also, a possible nucleation suppression due to the po- α′(t 1), t T/T , α′ and β are constants, and T is the − ≡ c c tential barrier can significantly reduce the number of ob- critical temperature. One obtains served defects. The obtained constraints on γ(T ) are used to access the impact on these claims. m c2 β λ = e , (3) 4πe2 α II. TEMPERATURE SENSITIVITY BOUND s | | and A superconductor undergoing a first-order phase tran- sition crosses different supercritical fields, displaying a metastable behavior, as shown in the phase diagram ξ =¯h/ 2me α . (4) | | of Figure 1. The superheating curve is given by the 2 p dV d V The coherence length at zero temperature is ξ0 = condition = 2 = 0, for Φ = 0, equivalent to ′ dΦ dΦ 6 ¯h/√2meα , with κ √β. The transition is second order α =9γ2/16β. The supercooling curve is given by the con- ∼ 2 if κ > 1/√2, and ξ0 is typically less than 0.04 µm; d V (Φ) ∼ dition dΦ2 = 0 for Φ = 0, correspondingto α = 0. The for κ < 1/√2, the transition is first order and ξ typi- 0 (unobservable) critical curve is given by V (0) = V (Φc) cally greater than 0.08 µm. It is commonly accepted dV (Φc) and = 0, where Φ is the non-vanishing minimum that, if there is no∼ applied magnetic field, one always dΦ c of the potential. This corresponds to α = γ2/2β. has a second-order phase transition, for all values of κ. ′ First order transitions arise from the external field term Assuming α = α (t 1) and γ(t) = δ t, we obtain for the superheating curve− in Eq. (1) if the sample has a characteristic dimension l > λ. This degeneracy of the phase transition at H =0 2 is, however, only verifiable to the current experimental ′ 9 δ α (t 1) = t2 , (7) sensitivity, and it can be argued that there is some yet − 16 β undetected intrinsic metastability, regardless of the ap- plied magnetic field. and Bearing in mind the analogy between condensed mat- ter and cosmology, we now briefly look at phase tran- 2 sitions in high energy physics. In thermal field theory 2 9 δ tsh = 1+ ′ . (8) 9 δ2 ∼ 16 α β (TFT) a first order phase transition arises due to 1-loop 1+ 1 ′ radiative corrections to a potential similar to that of Eq. − 4 α β q (2); a barrier between minima of the potential is created, Due to the presence of the cubic term in the potential of as these corrections give rise to a cubic scalar field term Eq. (5), the superheating curve shows a zero-field shift 2 ′ in temperature from Tc by (9δ /16α β)Tc. This shift, β if detected, would indicate an intrinsic metastability, in V (Φ) = αΦ2 γ Φ 3 + Φ4 , (5) − | | 2 the sense that it does not depend on the existence of an applied field. Since such temperature shift has not where γ(T ) = (√2/4π)e3T [12]. As before, β is assumed yet been signaled, the current experimental temperature ′ −3 to be constant and α = α (t 1) to depend linearly with sensitivity being ∆texp 10 [16], a bound on the slope temperature. − of γ is ∼ 668 TABLE I: Critical properties of Sn and Al TABLE II: Derived quantities and bounds for δ Material Tc (K) Hc(0) (G) ξ0 (µm) λ (nm) Material Sn Al ′ −25 −27 Sn 3.7 309 0.23 34 α (J) 1.15 10 2.38 10 3 × −54 × −56 Al 1.2 105 1.6 16 β (J.m ) 4.72 10 2.16 10 ′ × − × − α (eV 2) 3.61 10 1 7.45 10 3 × − × − β 9.45 10 4 4.32 10 6 × × 9 δ2 bound tsh shift δ(eV ) tsh shift δ(eV ) ′ < ∆texp .
Recommended publications
  • Anyon Theory in Gapped Many-Body Systems from Entanglement

    Anyon Theory in Gapped Many-Body Systems from Entanglement

    Anyon theory in gapped many-body systems from entanglement Dissertation Presented in Partial Fulfillment of the Requirements for the Degree Doctor of Philosophy in the Graduate School of The Ohio State University By Bowen Shi, B.S. Graduate Program in Department of Physics The Ohio State University 2020 Dissertation Committee: Professor Yuan-Ming Lu, Advisor Professor Daniel Gauthier Professor Stuart Raby Professor Mohit Randeria Professor David Penneys, Graduate Faculty Representative c Copyright by Bowen Shi 2020 Abstract In this thesis, we present a theoretical framework that can derive a general anyon theory for 2D gapped phases from an assumption on the entanglement entropy. We formulate 2D quantum states by assuming two entropic conditions on local regions, (a version of entanglement area law that we advocate). We introduce the information convex set, a set of locally indistinguishable density matrices naturally defined in our framework. We derive an isomorphism theorem and structure theorems of the information convex sets by studying the internal self-consistency. This line of derivation makes extensive usage of information-theoretic tools, e.g., strong subadditivity and the properties of quantum many-body states with conditional independence. The following properties of the anyon theory are rigorously derived from this framework. We define the superselection sectors (i.e., anyon types) and their fusion rules according to the structure of information convex sets. Antiparticles are shown to be well-defined and unique. The fusion rules are shown to satisfy a set of consistency conditions. The quantum dimension of each anyon type is defined, and we derive the well-known formula of topological entanglement entropy.
  • Field Theory of Topological Defects an Introduction to Solitons and Cosmology

    Field Theory of Topological Defects an Introduction to Solitons and Cosmology

    Field Theory of Topological Defects An Introduction to Solitons and Cosmology Viktor G. Matyas Abstract Topological defects are physical structures that may have arose during phase transitions in the early universe. In this report we provide a concise mathematical background in Group Theory and Algebraic Topology, which we use to systematically study soliton-like solutions to field equations. We then provide a link between these solutions and spontaneous symmetry breaking, which we use to explain how these defects might have formed during the early stages of the universe. We explicitly analyse multiple topo- logical defects such as Kinks and Vortices, and discuss the consequences they might have towards many aspects of modern cosmology and particle physics. Contents 1 Introduction 2 2 Topology and Homotopy Theory 2 2.1 Topological Spaces .................................... 2 2.2 Homotopy Classes and Groups .............................. 4 3 Lie Groups and Geometry 5 3.1 Groups, Representations and Orbits ........................... 5 3.2 Lie Groups and Manifolds ................................ 6 4 Field Theory and Solitons 7 4.1 Lagrangian Field Theory ................................. 7 4.2 Gauge Theory ...................................... 7 4.3 The Vacuum and Spotaneous Symmetry Breaking .................... 9 4.4 Vacuum Topology and Solitons .............................. 10 4.5 Bogomolny Bounds .................................... 11 5 Kinks 12 5.1 The φ4 Kink ....................................... 12 5.2 The Sine-Gordon Kink
  • Falaco Solitons 1

    Falaco Solitons 1

    Falaco Solitons 1 Falaco Solitons — Cosmic strings in a swimming pool. R. M. Kiehn Physics Department, University of Houston, Houston, TX 77004 USA. http://www.cartan.pair.com Updated May 10, 2004 ––––––––––––––––––––––––––––––––––––— Abstract: A new dynamical bifurcation mechanism finally explains the forma- tion of topological defects experimentally observed and defined in 1986 as Falaco Solitons. The Falaco Solitons are topologically universal phenomena created ex- perimentally by a macroscopic rotational dynamics in a continuous media with a discontinuity surface, such as that found in a swimming pool. The topologically coherent structure of Falaco Solitons replicates certain features found at all phys- ical scales, from spiral arm galaxies and cosmic strings to microscopic hadrons. The easy to replicate experiment indicates the creation of "stationary" thermo- dynamic states (or solitons) far from equilibrium, which are locally unstable but are globally stabilized. Several exact solutions to the Navier-Stokes equations are demonstrated to admit bifurcations to Falaco Solitons. It is conjectured that the universal coherent topological features of the Falaco Solitons can appear as cosmological realizations of Wheeler’s wormholes, could represent spin pairing mechanisms in the microscopic Fermi surface, and exhibit the confinement prob- lem of sub microscopic quarks on the end of a string, or are perhaps realizations of sub-submicroscopic strings connecting branes. Keywords: Falaco Solitons, Hopf Breathers, Cosmic Strings, Global Stability ––––––––––––––––––––––––––––––––––––— c CSDC Inc. 2004 Falaco Solitons 2 1 The Falaco Soliton - A Topological Defect in a swim- ming pool. 1.1 Preface During March of 1986, while visiting an old friend in Rio de Janeiro, Brazil, the present au- thor became aware of a significant topological event involving solitons that can be replicated experimentally by almost everyone with access to a swimming pool.
  • On the Relationship Between Topological and Geometric Defects E-Mail: Sgriffin@Lbl.Gov and Nicola.Spaldin@Mat.Ethz.Ch

    On the Relationship Between Topological and Geometric Defects E-Mail: [email protected] and [email protected]

    Journal of Physics: Condensed Matter TOPICAL REVIEW Related content - Characteristics and controllability of On the relationship between topological and vortices in ferromagnetics, ferroelectrics, and multiferroics geometric defects Yue Zheng and W J Chen - Multiferroics of spin origin Yoshinori Tokura, Shinichiro Seki and To cite this article: Sinéad M Griffin and Nicola A Spaldin 2017 J. Phys.: Condens. Matter 29 343001 Naoto Nagaosa - Quantum spin ice: a search for gapless quantum spin liquids in pyrochlore magnets M J P Gingras and P A McClarty View the article online for updates and enhancements. This content was downloaded from IP address 128.3.150.53 on 12/09/2017 at 23:26 IOP Journal of Physics: Condensed Matter Journal of Physics: Condensed Matter J. Phys.: Condens. Matter J. Phys.: Condens. Matter 29 (2017) 343001 (8pp) https://doi.org/10.1088/1361-648X/aa7b5c 29 Topical Review 2017 On the relationship between topological © 2017 IOP Publishing Ltd and geometric defects JCOMEL Sinéad M Griffin1,2,4 and Nicola A Spaldin3,5 343001 1 Molecular Foundry, Lawrence Berkeley National Laboratory, Berkeley, CA 94720, United States of America S M Griffin and N A Spaldin 2 Department of Physics, University of California Berkeley, Berkeley, CA 94720, United States of America 3 Materials Theory, ETH Zurich, Wolfgang-Pauli-Strasse 27, CH-8093 Zurich, Switzerland On the relationship between topological and geometric defects E-mail: [email protected] and [email protected] Printed in the UK Received 15 March 2017, revised 16 June 2017 Accepted for publication 23 June 2017 Published 25 July 2017 CM Abstract 10.1088/1361-648X/aa7b5c The study of topology in solids is undergoing a renaissance following renewed interest in the properties of ferroic domain walls as well as recent discoveries regarding skyrmionic lattices.
  • Boundary and Defect CFT: Open Problems and Applications

    Boundary and Defect CFT: Open Problems and Applications

    Boundary and Defect CFT: Open Problems and rspa.royalsocietypublishing.org Applications Research N. Andrei1, A. Bissi2, M. Buican3, J. Cardy4;5, P. Dorey6, N. Drukker7, Article submitted to journal J. Erdmenger8, D. Friedan1;9, D. Fursaev10, A. Konechny11;12, C. Kristjansen13, Subject Areas: Theoretical Physics, Mathematical I. Makabe7, Y. Nakayama14, A. O’Bannon15, Physics R. Parini16, B. Robinson15, S. Ryu17, Keywords: C. Schmidt-Colinet18, V. Schomerus19, Conformal Field Theory, Boundaries and Defects, Non-Perturbative C. Schweigert20, and G.M.T. Watts7 Effects, Holographic Duality, 1 Supersymmetry Dept. of Phys., Rutgers Univ., Piscataway, NJ, USA. 2Dept. of Phys. and Astro., Uppsala Univ., SE 3 Author for correspondence: CRST and SPA, Queen Mary Univ. of London, UK B. Robinson 4Dept. of Phys., Univ. of California, Berkeley, CA, USA e-mail: [email protected] 5All Souls College, Oxford, UK 6Dept. of Math. Sci., Durham Univ., UK 7Dept. of Maths, King’s College London, UK 8Julius-Maximilians-Univ. Würzburg, DE 9 Natural Science Inst., Univ. of Iceland, IS 10Dubna State Univ., Dubna, RU 11Dept. of Maths, Heriot-Watt Univ., Edinburgh, UK 12Maxwell Inst. for Math. Sci., Edinburgh, UK 13Niels Bohr Inst., Copenhagen Univ., , DK 14Dept. of Phys., Rikkyo Univ., Tokyo, JP 15STAG Research Centre, Univ. of Southampton, UK 16Department of Mathematics, University of York, UK 17J. Franck Inst. & KCTP., Univ. of Chicago, IL, USA 18Arnold Sommerfeld Center, Univ. München, DE arXiv:1810.05697v1 [hep-th] 12 Oct 2018 19DESY Theory Group, DESY Hamburg, Hamburg, DE 20Fachbereich Math., Univ. Hamburg, Hamburg, DE Proceedings of the workshop “Boundary and Defect Conformal Field Theory: Open Problems and Applications,” Chicheley Hall, Buckinghamshire, UK, 7-8 Sept.
  • Experimental Evidence for Maximal Surfaces in a 3 Dimensional Minkowski Space

    Experimental Evidence for Maximal Surfaces in a 3 Dimensional Minkowski Space

    Experimental Evidence for Maximal Surfaces in a 3 Dimensional Minkowski Space. R. M. Kiehn Emeritus Professor of Physics Physics Department, University of Houston, Houston, TX 77004 USA. http://www.cartan.pair.com c CSDC Inc. 2005 Draft° 2 Updated June 12, 2005 –––––––––––––––––––––––––– Abstract: Conventional physical dogma, justified by the local success of Newtonian dynamics for particles, assigns a Euclidean metric with signature (plus, plus, plus) to the three spatial di- mensions. Minimal surfaces are of zero mean curvature and neg- ative Gauss curvature in a Euclidean space, which supports affine evolutionary processes. However, experimental evidence now in- dicates that the non-affine dynamics of a fluid admits a better description in terms of a 3 dimensional space with a Minkowski metric of signature (plus, plus, minus). Three dimensional spaces with a Minkowski metric admit maximal surfaces of zero mean curvature, with conical or isolated singularities, and with posi- tive Gauss curvature, in contrast to Euclidean 3D metrics. Such properties are also associated with the Hopf map, which generates two surfaces of zero mean curvature and positive Gauss curvature in a 4D Euclidean space. Falaco Solitons, easily created as topo- logical defects in a swimming pool, are experimental artifacts of maximal surfaces (of zero mean curvature, but positive Gauss curvature) in a 3D Minkowski space. The topological defects in the otherwise flat surface of fluid density discontinuity appear as a pair of zero mean curvature surfaces, with a conical singularity at each end. The two conical singularies of the Falaco Soliton pair appear to be connected with a 1D string under tension.
  • Topological Defects in Cosmology

    Topological Defects in Cosmology

    Topological defects in cosmology Ossi Tapio February 4, 2013 Abstract In this dissertation I study topological defects by performing numerical sim- ulations of classical scalar field theories in one spatial dimension. I devise three methods of counting defect densities and run multiple simulations to find out how different counting methods compare. I discover a difference that might help in the interpretation of future simulations of topological defects. I also run multiple simulations with varying parameters to see how the density of topological defects changes under different conditions. With this data I observe that a low rate of energy damping will have interesting and surprising effects on the defect density. Introduction The standard theory of beginning of the Universe is the so called Hot Big Bang model. This theory stipulates that all matter and space was at the beginning of time compressed to an extremely small and extremely hot point and that this point started to expand and cool. In the very early state of the Universe, the energy density was so enormous that all interactions were indistinguishable from each other. Approximately 10−43 seconds after the Big Bang a phase transition occurred, triggered by the dilution of the en- ergy density, causing gravity to separate from rest of the interactions. The Universe kept expanding and cooling and 10−36 seconds after the Big Bang the strong interactions separated from the electroweak interactions and phe- nomenon known as cosmic inflation happened. This phase transition sepa- rating the strong interaction from the electroweak interaction should have created a large number of magnetic monopoles and anti-monopoles.
  • Topological Defects and Cosmology

    Topological Defects and Cosmology

    PRAMANA Indian Academy of Sciences Vol. 51, Nos 1 & 2, --journal of July/August 1998 physics pp. 191-204 Topological defects and cosmology ROBERT H BRANDENBERGER Physics Department, Brown University, Providence, RI 02912, USA Abstract. Many particle physics models of matter admit solutions corresponding to stable or long-lived topological defects. In the context of standard cosmology it is then unavoidable that such defects will form during phase transitions in the very early Universe. Certain types of defects lead to disastrous consequences for cosmology, others may play a useful role, as possible seeds for the formation of structure in the Universe, or in mediating baryon number violating processes. In all cases, topological defects lead to a fruitful interplay between particle physics and cosmology. Keywords. Cosmic strings; cosmology; structure formation; baryogenesis. PACS No. 98.80 1. Introduction Most aspects of high energy physics beyond the standard model can only be tested by going to energies far greater than those which present accelerators can provide. Fortunately, the marriage between particle physics and cosmology has provided a way to 'experimentally' test the new theories of fundamental forces. The key realization is that physics of the very early Universe may explain the origin of the structure on the scales of galaxies and beyond. It now appears that a rich set of data concerning the nonrandom distribution of matter on a wide range of cosmological scales, and on the anisotropies in the cosmic microwave background (CMB), may potentially be explained by high energy physics. Topological defects provide one class of mechanisms for generating the initial density fluctuations [1].
  • Topological Defect Arrays in Nematic Liquid Crystals Assisted by Polymeric Pillar Arrays: Effect of the Geometry of Pillars

    Topological Defect Arrays in Nematic Liquid Crystals Assisted by Polymeric Pillar Arrays: Effect of the Geometry of Pillars

    crystals Article Topological Defect Arrays in Nematic Liquid Crystals Assisted by Polymeric Pillar Arrays: Effect of the Geometry of Pillars MinSu Kim and Francesca Serra * Department of Physics and Astronomy, Johns Hopkins University, Baltimore, MD 21218, USA; [email protected] * Correspondence: [email protected]; Tel.: +1-410-516-0248 Received: 23 March 2020; Accepted: 16 April 2020; Published: 18 April 2020 Abstract: Topological defects that spontaneously occur in condensed matter and structured fluids such as liquid crystals are useful for their elastic and optical properties, but often the applicability of defect arrays to optics and photonic devices relies on the regularity and tunability of the system. In our recent work [Adv. Opt. Mater. 8, 1900991 (2020)], we showed the formation of regular, reconfigurable, and scalable patterns by exploiting the elastic response of a defect array in liquid crystals in the presence of a polymeric pillar array. In this work, we experimentally investigate the role of size and shape of the pillars on the defect array. We find that the pillar size and geometry provide additional means to regulate the response time, the threshold voltage for the defects’ formation, and the spatial arrangement of the defects. Keywords: liquid crystals; soft matter; defect arrays; diffraction 1. Introduction After mastering techniques to create perfect liquid crystal (LC) displays without any imperfections or defects, for the last 20 years physicists and engineers have looked for ways to control and utilize topological defects in LCs [1–3]. In nematic LCs, the long-range molecular order is represented by a headless vector called the director [4].
  • Cosmic Strings and Topological Defects

    Cosmic Strings and Topological Defects

    Cosmic Strings and Topological Defects Jiawen Liu December 9, 2012 Abstract In this review article, we point out spontaneous symmetry breaking is closely related to the emergence of the topological defects. Basic definitions and dynamics of the domain walls are introduced in the second section. Finally, we worked out an example of the spherical domain wall by using semi-classical approach. 1 1 Introduction Cosmic strings are one dimensional topological defects which may arise from a symmetry breaking phase transition of the early universe. Consider the geometry of the early universe is a non-connected vacuum manifold, M. Cosmic strings are characterized by non-trivial fundamental group of the manifold, M(π1(M) 6= I), which is an analog of the topological defect of two dimensional vortex. The manifold, M is not contractible which means the singularity corresponding to a hole cannot be removed by continuous deformation. There are other topological defects in the curved spacetime such as monopoles, domain walls, and textures. This expository article is mainly focused on the basics of the cosmic strings and topological defects. We basically give a short account of the theory based on the book by Vilenkin and Shellard. The article is organized as follows. First, introduce the origin of the topological defects in the uni- verse. In the book, they argue that the symmetry of Higgs fields (scalar fields) break because of the non-zero expectation value of the ground state. Hence, we can heuristically determine that the manifold has some non-trivial topological properties. Second, we explain the concept of domain walls and their non-trivial topological properties.
  • Interacting Quantum Field Theories and Topological Defects

    Interacting Quantum Field Theories and Topological Defects

    Interacting Quantum Field Theories and Topological Defects A. Flachi and V. Vitagliano Department of Physics & Research and Education Center for Natural Sciences, Keio University, 4-1-1 Hiyoshi, Kanagawa 223-8521, Japan In this talk we present a recent analysis of interacting quantum field theories on a curved manifold with a topological defect constructed by geometrically deforming a lattice. We present an explicit example where curvature and boundary conditions compete in altering the way the quantum vacuum is destabilized. We show that the competing action of the locally induced curvature and of boundary conditions generated by the non-trivial topology allows configurations where symmetries can be spontaneously broken close to the defect core. Inspired by this effect, we propose a novel mechanism to induce a superconducting phase by triggering particle condensation along cosmic strings. As the energy scales of a physical system become higher, non-perturbative effects get into the game and the system is said to have entered an strongly coupled regime. Remarkable examples of strongly coupled systems include QCD, high temperature superconductors and the very primordial plasma filling the universe a few instants after the big bang. Interactions are also important in describing the propagation of conducting electrons in graphene. Precise study of strong coupled dynamics is only possible at the cost of demanding numerical simulations. On the other hand, general phenomenological guidelines for the study of strongly coupled systems can be precisely draft exploiting mathematical considerations on the underlying symmetries. The physics of symmetry breaking, in fact, notably relies on exact mathematical statements which are intimately non-perturbative, as in the case of the Goldstone theorem.
  • Topological Quantum Field Theory and the Geometric Langlands Correspondence

    Topological Quantum Field Theory and the Geometric Langlands Correspondence

    Topological Quantum Field Theory and the Geometric Langlands Correspondence Thesis by Kevin Setter In Partial Fulfillment of the Requirements for the Degree of Doctor of Philosophy California Institute of Technology Pasadena, California 2013 (Defended August 24, 2012) ii c 2013 Kevin Setter All Rights Reserved iii Dedicated with love and gratitude to my parents. iv Acknowledgments I would like to thank my advisor Anton Kapustin, whose ideas are central to this thesis, from whom I learned an immense amount, and who kept me on track during the writing process with guidance and support. Thank you to Sergei Gukov for his guidance and support as well. Many thanks to Carol Silberstein and the members of the theory group, especially Ketan Vyas, Paul Cook, Jie Yang, Sakura Schafer-Namecki, Tudor Dimofte, Miguel Bandres, Itamar Yaakov, Brian Willett, and Denis Bashkirov for discussions and support. Thank you to Lee Coleman and Cristina Dezan for their copious insights into life and more. I acknowledge the generous support of the Jack Kent Cooke Foundation. Warm gratitude to my gym buddies Chris Wegg and Nate Bode, and to my friends Lucia Cordeiro-Drever, Esi Alizadeh, Laura Book, Tristan Smith, and Hernan Garcia, for their support and inspiration during my time at Caltech. Much love and gratitude to my parents for their tireless support and understanding. Finally, my deepest gratitude to Camilla Berretta | So are you to my thoughts as food to life / Or as sweet-season'd showers are to the ground. v Abstract In the pioneering work [1] of A. Kapustin and E. Witten, the geometric Langlands program of number theory was shown to be intimately related to duality of GL-twisted N = 4 super Yang-Mills theory compactified on a Riemann surface.