682 research outputs found
Dirac fermion duality and the parity anomaly
We present a derivation of the recently discovered duality between the free
massless (2+1)-dimensional Dirac fermion and QED. Our derivation is based
on a regularized lattice model of the Dirac fermion and is similar to the more
familiar derivation of the boson-vortex duality. It also highlights the
important role played by the parity anomaly, which is somewhat less obvious in
other discussions of this duality in the literature.Comment: 5 pages, typo correcte
Dynamical density response and optical conductivity in topological metals
Topological metals continue to attract attention as novel gapless states of
matter. While there by now exists an exhaustive classification of possible
topologically nontrivial metallic states, their observable properties, that
follow from the electronic structure topology, are less well understood. Here
we present a study of the electromagnetic response of three-dimensional
topological metals with Weyl or Dirac nodes in the spectrum, which systematizes
and extends earlier pioneering studies. In particular, we argue that a
smoking-gun feature of the chiral anomaly in topological metals is the
existence of propagating chiral density modes even in the regime of weak
magnetic fields. We also demonstrate that the optical conductivity of such
metals exhibits an extra peak, which exists on top of the standard metallic
Drude peak. The spectral weight of this peak is transferred from high
frequencies and its width is proportional to the chiral charge relaxation rate.Comment: 10 pages, 2 figures, published versio
Mirror Anomaly in Dirac Semimetals
We demonstrate that, apart from the chiral anomaly, Dirac semimetals possess
another quantum anomaly, which we call the mirror anomaly, and which manifests
in a singular response of the Dirac semimetal to an applied magnetic field.
Namely, the anomalous Hall conductivity exhibits step-function singularities
when the field is rotated. We show that this phenomenon is closely analogous to
the parity anomaly of (2+1)-dimensional Dirac fermions, but with mirror
symmetry, which we demonstrate emerges near any Dirac point at a time reversal
invariant momentum, replacing the parity symmetry.Comment: 5 pages, 3 figures. Typos corrected. Published versio
Weyl Metals
Weyl metal is the first example of a conducting material with a nontrivial
electronic structure topology, making it distinct from an ordinary metal.
Unlike in insulators, the nontrivial topology is not related to invariants,
associated with completely filled bands, but with ones, associated with the
Fermi surface. The Fermi surface of a topological metal consists of
disconnected sheets, each enclosing a Weyl node, which is a point of contact
between two nondegenerate bands. Such a point contact acts as a source of Berry
curvature, or a magnetic monopole in momentum space. Its charge, or the flux of
the Berry curvature through the enclosing Fermi surface sheet, is a topological
invariant. We review the current state of this rapidly growing field, with a
focus on bulk transport phenomena in topological metals.Comment: 21 pages, 6 figures. Review article, submitted to Annual Reviews of
Condensed Matter Physics. Added references and fixed a formatting proble
Giant Planar Hall Effect in Topological Metals
Much excitement has been generated recently by the experimental observation
of the chiral anomaly in condensed matter physics. This manifests as strong
negative longitudinal magnetoresistance and has so far been clearly observed in
NaBi, ZrTe, and GdPtBi. In this work we point out that the chiral
anomaly must lead to another effect in topological metals, that has been
overlooked so far: Giant Planar Hall Effect (GPHE), which is the appearance of
a large transverse voltage when the in plane magnetic field is not aligned with
the current. Moreover, we demonstrate that the GPHE is closely related to the
angular narrowing of the negative longitudinal magnetoresistance signal,
observed experimentally.Comment: 5 pages, 2 figures, published versio
Chiral anomaly and transport in Weyl metals
We present an overview of our recent work on transport phenomena in Weyl
metals, which may be connected to their nontrivial topological properties,
particularly to chiral anomaly. We argue that there are two basic phenomena,
which are related to chiral anomaly in Weyl metals: Anomalous Hall Effect (AHE)
and Chiral Magnetic Effect (CME). While AHE is in principle present in any
ferromagnetic metal, we demonstrate that a magnetic Weyl metal is distinguished
from an ordinary ferromagnetic metal by the absence of the extrinsic and the
Fermi surface part of the intrinsic contributions to the AHE, as long as the
Fermi energy is sufficiently close to the Weyl nodes. The AHE in a Weyl metal
is thus shown to be a purely intrinsic, universal property, fully determined by
the location of the Weyl nodes in the first Brillouin zone. In other words, a
ferromagnetic Weyl metal may be thought of as the only example of a
ferromagnetic metal with a purely intrinsic AHE. We further develop a fully
microscopic theory of diffusive magnetotransport in Weyl metals. We derive
coupled diffusion equations for the total and axial (i.e. node-antisymmetric)
charge densities and show that chiral anomaly manifests as a
magnetic-field-induced coupling between them. We demonstrate that an
experimentally-observable consequence of CME in magnetotransport in Weyl metals
is a quadratic negative magnetoresistance, which will dominate all other
contributions to magnetoresistance under certain conditions and may be regarded
as a smoking-gun transport characteristic, unique to Weyl metals.Comment: 35 pages, 7 figures. Topical review of our recent work on transport
in Weyl metal
Negative longitudinal magnetoresistance in Dirac and Weyl metals
It has recently been found that Dirac and Weyl metals are characterized by an
unusual weak-field longitudinal magnetoresistance: large, negative, and
quadratic in the magnetic field. This has been shown to arise from chiral
anomaly, i.e. nonconservation of the chiral charge in the presence of external
electric and magnetic fields, oriented collinearly. In this paper we report on
a theory of this effect in both Dirac and Weyl metals. We demonstrate that this
phenomenon contains two important ingredients. One is the
magnetic-field-induced coupling between the chiral and the total (or vector, in
relativistic field theory terminology) charge densities. This arises from the
Berry curvature and is present in principle whenever the Berry curvature is
nonzero, i.e. is nonspecific to Dirac and Weyl metals. This coupling, however,
leads to a large negative quadratic magnetoresistance only when the second
ingredient is present, namely when the chiral charge density is a nearly
conserved quantity with a long relaxation time. This property is specific to
Dirac and Weyl metals and is realized only when the Fermi energy is close to
Dirac or Weyl nodes, expressing an important low-energy property of these
materials, emergent chiral symmetry.Comment: 12+ pages, 1 figure, published versio
Topological response in ferromagnets
We present a theory of the intrinsic anomalous Hall effect in a model of a
doped Weyl semimetal, which serves here as the simplest toy model of a generic
three-dimensional metallic ferromagnet with Weyl nodes in the electronic
structure. We analytically evaluate the anomalous Hall conductivity as a
function of doping, which allows us to explicitly separate the Fermi surface
and non Fermi surface contributions to the Hall conductivity by carefully
evaluating the zero frequency and zero wavevector limits of the corresponding
response function. We show that this separation agrees with the one suggested a
long time ago in the context of the quantum Hall effect by Streda.Comment: 6 pages, 2 figures, published versio
Chiral Anomaly and Diffusive Magnetotransport in Weyl Metals
We present a microscopic theory of diffusive magnetotransport in Weyl metals
and clarify its relation to chiral anomaly. We derive coupled diffusion
equations for the total and axial charge densities and show that chiral anomaly
manifests as a magnetic-field-induced coupling between them. We demonstrate
that a universal experimentally-observable consequence of this coupling in
magnetotransport in Weyl metals is a quadratic negative magnetoresistance,
which will dominate all other contributions to magnetoresistance under certain
conditions.Comment: 5 pages, no figures, published versio
Band structure and unconventional electronic topology of CoSi
Crystalline semimetals with certain space group symmetries may possess
unusual electronic structure topology, distinct from the conventional Weyl and
Dirac semimetals. Characteristic property of these materials is the existence
of band-touching points with multiple (higher than two-fold) degeneracy and
nonzero topological charge. CoSi is a representative of this group of materials
exhibiting the so-called "new fermions". We report on an ab initio calculation
of the electronic structure of CoSi using density functional methods, taking
into account the spin-orbit interactions. We demonstrate the existence of
band-touching nodes with four- and six-fold degeneracy, located at the
and points in the first Brillouin zone and near the Fermi energy. We show
that these band-touching points carry topological charges of and
describe the resulting Fermi arc surface states, connecting the projections of
these nodes onto the surface Brillouin zone. We also discuss the influence of
many body corrections on the electronic band structure and the
topological properties of CoSi.Comment: 12 pages, 6 figure
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