Electro- and magnetostatics of topological insulators as modeled by planar, spherical, and cylindrical<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mi>θ</mml:mi></mml:math>boundaries: Green’s function approach

Martín-Ruiz, A.; Cambiaso, M.; Urrutia, L. F.

doi:10.1103/physrevd.93.045022

Cited by 46 publications

(31 citation statements)

References 82 publications

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“…However, the same result can also be obtained using far superior techniques, such as the SL(2, Z) electric-magnetic duality group of TIs [19] and Green's function techniques [20][21][22][23]. In short, let us consider the geometry of fig.…”

Section: Electromagnetic Response Of Tismentioning

confidence: 83%

Dynamics of a Rydberg hydrogen atom near a topologically insulating surface

Martín-Ruiz

Chan-López

2017

EPL

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-Interactions of atoms and molecules with surfaces PACS 05.45.-a -Nonlinear dynamical systems and chaos PACS 11.15.Yc -Chern-Simons gauge theory Abstract -We investigate the classical dynamics of a Rydberg hydrogen atom near the surface of a planar topological insulator. The system is described by a Hamiltonian consisting of the freehydrogen part and the hydrogen-surface potential. The latter includes the interactions between the electron and both image electric charges and image magnetic monopoles. Owing to the axial symmetry, the z component of angular momentum lz is conserved. Here we consider the lz = 0 case. The structure of the phase space is explored extensively by means of numerical techniques and Poincaré surfaces of section for the recently discovered topological insulator TlBiSe2. The phase space of the system is separated into regions of vibrational and rotational motion. We show that vibrational-rotational-vibrational type transitions can be tuned with the topological magnetoelectric polarizability.

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Section: Electromagnetic Response Of Tismentioning

confidence: 83%

Dynamics of a Rydberg hydrogen atom near a topologically insulating surface

Martín-Ruiz

Chan-López

2017

EPL

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“…where the electric field E = E 1 , E 2 has two components and the magnetic field B has just one component. Using the fact that F μν = ∂ μ A ν − ∂ ν A μ , from the Eq's (42) and (37), we obtain…”

Section: Electromagnetic Fieldmentioning

confidence: 99%

“…There is also a generalization of the Chern-Simos electrodynamics in 3 + 1 dimensions, the so called Carroll-Field-Jackiw model [37], which exhibits Lorentz symmetry breaking and whose corresponding electrostatics and magnetostatics has been studied thoroughly in reference [38], as well as the Casimir Effect, in references [39,40]. Another coupling involving the dual gauge field strength tensor in 3 + 1 dimensions is the so called axion θ -electrodynamics, which can be used to describe insulators with boundaries [41][42][43][44].…”

Section: Introductionmentioning

confidence: 99%

New point-like sources and a conducting surface in Maxwell–Chern–Simons electrodynamics

Borges¹,

Ribeiro²,

Oliveira³

et al. 2020

Eur. Phys. J. C

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We investigate some aspects of the Maxwell-Chern-Simons electrodynamics focusing on physical effects produced by the presence of stationary sources and a perfectly conducting plate (mirror). Specifically, in addition to point charges, we propose two new types of point-like sources called topological source and Dirac point, and we also consider physical effects in various configurations that involve them. We show that the Dirac point is the source of the vortex field configurations. The propagator of the gauge field due to the presence of a conducting plate and the interaction forces between the plate and point-like sources are computed. It is shown that the image method is valid for the point-like charges as well as for Dirac points. For the topological source we show that the image method is not valid and the symmetry of spatial refection on the mirror is broken. In all setups considered, it is shown that the topological source leads to the emergence of torques.PACS numbers: I. INTRODUCTIONPlanar models in Quantum Field Theory have several interesting features, both theoretical and experimental. We can mention, for instance, the change in the fermions behavior in comparison with the standard classical and quantum electrodynamics [1]. One of the most important class of models of this kind is the so called Maxwell-Chern-Simons electrodynamics [2], or Abelian topological massive gauge theory [3], which is relevant because it is simultaneously massive and gauge invariant. Theoretical aspects of Maxwell-Chern-Simons electrodynamics have been investigated in Casimir effect [4][5][6][7][8][9], quantum dissipation of harmonic systems [10], quantum electrodynamics (QED 3 ) [11-15], dynamical mass generation [16,17], condensed matter physics (see, for instance, Ref.[24] and references therein), description of graphene properties [18][19][20][21][22][23], noncommutativity [25-28], strings theory [29], dynamics of vortices [30,31], and with a planar boundary [32][33][34][35][36], to mention just a few. In fact, there is a vast literature concerning this model.There is also a generalization of the Chern-Simos electrodynamics in 3 + 1 dimensions, the so called Carroll-Field-Jackiw model [37], which exhibits Lorentz symmetry breaking and whose corresponding electrostatics and magnetostatics has been studied thoroughly in reference [38], as well as the Casimir Effect, in references [39,40]. Another coupling involving the dual gauge field strength tensor in 3 + 1 dimensions is the so called axion θ-electrodynamics, which can be used to describe insulators with boundaries [41][42][43][44].In the context of Casimir Effect, in 3 + 1 dimensions, Chern-Simons surfaces can also be used to obtain Casimir repulsion setups with planar symmetry [45]. In higher dimensions, the Casimir force has been studied in Randall-Sundrum models [46], which can be interpreted as a kind of ground state for Chern-Simons gravity [47].Regarding the Maxwell-Chern-Simons electrodynamics, there are two interesting questions no yet explored in the literature, ...

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“…In a linear, continuous, ponderable medium, general constitutive relations can be envisaged as a theoretical possibility [28], which gained great attention with the advent of topological insulators [29,30]. In systems of this kind, it holds that D…”

Section: Basic Aspects Of Electrodynamics In Mattermentioning

confidence: 99%

Magnetic-conductivity effects on electromagnetic propagation in dispersive matter

et al. 2020

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The chiral magnetic effect (CME) has been investigated as a new transport phenomenon in condensed matter. Such an effect appears in systems with chiral fermions and involves an electric current generated by a magnetic field by means of an "exotic" magnetic conductivity. This effect can also be connected with extensions of the usual Ohm's law either in magnetohydrodynamics or in Lorentz-violating scenarios. In this work, we study the classical propagation of electromagnetic waves in isotropic dispersive matter subject to a generalized Ohm's law. The latter involves currents linear in the magnetic field and implies scenarios inducing parity violation. We pay special attention to the case of a vanishing electric conductivity. For a diagonal magnetic conductivity, which includes the CME, the refractive index is modified such that it leads to birefringence. For a nondiagonal magnetic conductivity, modified refractive indices exhibiting imaginary parts occur ascribing a conducting behavior to a usual dielectric medium. Our findings provide new insights into typical material properties associated with a magnetic conductivity.

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Electro- and magnetostatics of topological insulators as modeled by planar, spherical, and cylindricalθboundaries: Green’s function approach

Cited by 46 publications

References 82 publications

Dynamics of a Rydberg hydrogen atom near a topologically insulating surface

Dynamics of a Rydberg hydrogen atom near a topologically insulating surface

New point-like sources and a conducting surface in Maxwell–Chern–Simons electrodynamics

Magnetic-conductivity effects on electromagnetic propagation in dispersive matter

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