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2017 | Buch

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Dirac Matter

herausgegeben von: Bertrand Duplantier, Vincent Rivasseau, Jean-Nöel Fuchs

Verlag: Springer International Publishing

Buchreihe : Progress in Mathematical Physics

Enthalten in: Springer Professional "Wirtschaft+Technik" , Springer Professional "Technik"

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Über dieses Buch

This fifteenth volume of the Poincare Seminar Series, Dirac Matter, describes the surprising resurgence, as a low-energy effective theory of conducting electrons in many condensed matter systems, including graphene and topological insulators, of the famous equation originally invented by P.A.M. Dirac for relativistic quantum

mechanics. In five highly pedagogical articles, as befits their origin in lectures to a broad scientific audience, this book explains why Dirac matters. Highlights include the detailed "Graphene and Relativistic Quantum Physics", written by the experimental pioneer, Philip Kim, and devoted to graphene, a form

of carbon crystallized in a two-dimensional hexagonal lattice, from its discovery in 2004-2005 by the future Nobel prize winners Kostya Novoselov and Andre Geim to the so-called relativistic quantum Hall effect; the review entitled "Dirac Fermions in Condensed Matter and Beyond", written by two prominent theoreticians, Mark Goerbig and Gilles Montambaux, who consider many other materials than graphene, collectively known as "Dirac matter", and offer a thorough description of the merging transition of Dirac cones that occurs in the energy spectrum, in various experiments involving stretching of the microscopic hexagonal lattice; the third contribution, entitled "Quantum Transport in Graphene: Impurity Scattering as a Probe of the Dirac

Spectrum", given by Hélène Bouchiat, a leading experimentalist in mesoscopic physics, with Sophie Guéron and Chuan Li, shows how measuring electrical transport, in particular magneto-transport in real graphene devices - contaminated by impurities and hence exhibiting a diffusive regime - allows one to deeply probe the Dirac nature of electrons. The last two contributions focus on topological insulators; in the authoritative "Experimental Signatures of Topological Insulators", Laurent Lévy reviews recent experimental progress in the physics of mercury-telluride samples under strain, which demonstrates that the surface of a three-dimensional topological insulator hosts a two-dimensional massless Dirac metal; the illuminating final contribution by David Carpentier, entitled "Topology of Bands in Solids: From Insulators to Dirac Matter", provides a geometric description of Bloch wave functions in terms of Berry phases and parallel transport, and of their topological classification in terms of invariants such as Chern numbers, and ends with a perspective on three-dimensional semi-metals as described by the Weyl equation. This book will be of broad general interest to physicists, mathematicians, and historians of science.

Inhaltsverzeichnis

Frontmatter

Graphene and Relativistic Quantum Physics

Abstract

The honeycomb lattice structure of graphene requires an additional degree of freedom, termed as pseudo spin, to describe the orbital wave functions sitting in two different sublattices of the honeycomb lattice. In the low energy spectrum of graphene near the charge neutrality point, where the linear carrier dispersion mimics the quasi-relativistic dispersion relation, pseudo spin replaces the role of real spin in the usual Dirac Fermion spectrum. The exotic quantum transport behavior discovered in graphene, such as the unusual half-integer quantum Hall effect and Klein tunneling effect, are a direct consequence of the pseudo spin rotation. In this chapter we will discuss the non-trivial Berry phase arising from the pseudo spin rotation in monolayer graphene under a magnetic field and its experimental consequences.

Philip Kim

Dirac Fermions in Condensed Matter and Beyond

Abstract

This review aims at a theoretical discussion of Dirac points in twodimensional systems. Whereas Dirac points and Dirac fermions are prominent low-energy electrons in graphene (two-dimensional graphite), research on Dirac fermions in low-energy physics has spread beyond condensed matter to artificial graphene systems. In these alternative systems, a large versatility in the manipulation of the relevant band parameters can be achieved. This allows for a systematic study of the motion and different possible fusions of Dirac points, which are beyond the physical limits of graphene. We introduce the basic properties of Dirac fermions and the motion of Dirac points here and aim at a topological classification of these motions. The theoretical concepts are illustrated in particular model systems.

Mark Goerbig, Gilles Montambaux

Quantum Transport in Graphene: Impurity Scattering as a Probe of the Dirac Spectrum

Abstract

Since the very first investigations of the electronic properties of graphene, the nature of the scattering disorder potential has been shown to play an essential role in determining the carrier density dependence of the conductance. Impurity scattering is characterized by two different times, the transport and elastic scattering times, which are sensitive to the particular Dirac spectrum of graphene. The analysis of the ratio between these two times gives insight on the nature (neutral or charged) and range of the scatterers. We show how to extract these two times from magneto-transport measurements and analyze their differences in monolayer and bilayer Graphene in relation with the different symmetry properties of their band structure and wave functions. It is found that whereas short range impurity scattering is the dominant mechanism limiting the classical transport, phase coherent mesoscopic transport is very sensitive to long range disorder. In particular, the formation of electron/hole puddles in the vicinity of the charge neutrality point strongly affects the transport of Andreev pairs in the presence of superconducting electrodes. We will also discuss the modification of electronic properties of graphene in the presence of adsorbed atoms and molecules and in particular focus on spin dependent scattering on adsorbates leading to a spin orbit interaction. There is indeed a big interest in controlling and inducing spin orbit interactions in graphene. One can hope to induce and detect a spin Hall effect with a great potential impact in graphene based spintronic devices and ultimately reach a regime of quantum spin Hall physics. In contrast with these very short range scatterers, we discuss the possibility to engineer networks of longer range strained regions in which electronic properties are locally modified by transferring graphene on arrays of silicon oxyde nanopillars.

Chuan Li, Sophie Guéron, Hélène Bouchiat

Experimental Signatures of Topological Insulators

Abstract

Energy bands in solids describe quantum states in periodic crystals. When a quantum state is wound around the Brillouin zone, it acquires a quantum phase. For a completely filled band, the global phase acquired in this winding is a topological property of the band. For 3D solid with timereversal symmetry, there are two topological classes corresponding to a ±1 sign. A signature of topological solids (minus sign) is the presence of conducting surface states with a relativistic dispersion, similar to graphene. They can be observed in angle resolved photo-emission which is able to reconstruct their energy-momentum dispersion below the Fermi level. Some of the experimental signatures of these topological states in strained Mercury-Telluride are presented: their Dirac spectra measured at the SOLEIL synchrotron, the ambipolar sign of their surface charge carriers, the topological phase in their Landau-level quantization, and the weak-antilocalization peak in magnetotransport also controlled by the π-topological phase.

Laurent Lévy

Topology of Bands in Solids: From Insulators to Dirac Matter

Abstract

Bloch theory describes the electronic states in crystals whose energies are distributed as bands over the Brillouin zone. The electronic states corresponding to a (few) isolated energy band(s) thus constitute a vector bundle. The topological properties of these vector bundles provide new characteristics of the corresponding electronic phases. We review some of these properties in the case of (topological) insulators and semi-metals.

David Carpentier

Titel: Dirac Matter
herausgegeben von: Bertrand Duplantier
Vincent Rivasseau
Jean-Nöel Fuchs
Verlag: Springer International Publishing
Electronic ISBN: 978-3-319-32536-1
Print ISBN: 978-3-319-32535-4
DOI: https://doi.org/10.1007/978-3-319-32536-1

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