Characterisation and representation of non-dissipative electromagnetic medium with two Lorentz null cones

Dahl, Matias F.

doi:10.1063/1.4773832

Cited by 8 publications

(5 citation statements)

References 37 publications

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“…We remark that uniaxial crystals are not the only media with bi-metric Fresnel polynomials but that two other classes of constitutive laws with this property exist [5]. The matrix Q ab takes the form…”

Section: A Uniaxial Crystalsmentioning

confidence: 99%

Electromagnetic potential in pre-metric electrodynamics: Causal structure, propagators and quantization

Pfeifer

Siemssen

2016

Phys. Rev. D

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An axiomatic approach to electrodynamics reveals that Maxwell electrodynamics is just one instance of a variety of theories for which the name electrodynamics is justified. They all have in common that their fundamental input are Maxwell's equations dF ¼ 0 (or F ¼ dA) and dH ¼ J and a constitutive law H ¼ #F which relates the field strength two-form F and the excitation two-form H. A local and linear constitutive law defines what is called local and linear pre-metric electrodynamics whose best known application is the effective description of electrodynamics inside media including, e.g., birefringence. We analyze the classical theory of the electromagnetic potential A before we use methods familiar from mathematical quantum field theory in curved spacetimes to quantize it in a locally covariant way. Our analysis of the classical theory contains the derivation of retarded and advanced propagators, the analysis of the causal structure on the basis of the constitutive law (instead of a metric) and a discussion of the classical phase space. This classical analysis sets the stage for the construction of the quantum field algebra and quantum states. Here one sees, among other things, that a microlocal spectrum condition can be formulated in this more general setting.

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Section: A Uniaxial Crystalsmentioning

confidence: 99%

Electromagnetic potential in pre-metric electrodynamics: Causal structure, propagators and quantization

Pfeifer

Siemssen

2016

Phys. Rev. D

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“…In this talk, uncommon and beautiful Fresnel surfaces are visualized and explored, both by resorting to the literature [4], [13], [16], [18], [20], and by generating new images such as Figure 4. We also describe the physical specifications of the (meta)materials that correspond to the surfaces.…”

Section: Unusual and Beautiful Fresnel Surfacesmentioning

confidence: 99%

Electromagnetic wave propagation in metamaterials: A visual guide to Fresnel-Kummer surfaces and their singular points

Favaro

2016

2016 URSI International Symposium on Electromagnetic Theory (EMTS)

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Abstract-The propagation of light through bianisotropic materials is studied in the geometrical optics approximation. For that purpose, we use the quartic general dispersion equation specified by the Tamm-Rubilar tensor, which is cubic in the electromagnetic response tensor of the medium. A collection of different and remarkable Fresnel (wave) surfaces is gathered, and unified via the projective geometry of Kummer surfaces.Keywords: Geometrical optics, wave surfaces, bianisotropic media, Kummer surfaces, Tamm-Rubilar tensor

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“…Media such that D(ω, k) is the product of two quadratic polynomials are well studied. Examples include hyperbolic metamaterials [31,32], uniaxial media [29,30], nematic liquid crystals [33] and decomposable (DCM) media [34,35]. If the two quadratic factors coincide, the material displays no birefringence.…”

Section: Dispersion Equationmentioning

confidence: 99%

Plane wave propagation in extreme magnetoelectric (EME) medium

Lindell

Sihvola

Favaro

2016

2016 URSI International Symposium on Electromagnetic Theory (EMTS)

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The extreme magnetoelectric medium (EME medium) is defined in terms of two medium dyadics, α, producing electric polarization by the magnetic field and β, producing magnetic polarization by the electric field. Plane-wave propagation of time-harmonic fields of fixed finite frequency in the EME medium is studied. It is shown that (if ω = 0) the dispersion equation has a cubic and homogeneous form, whence the wave vector k is either zero or has arbitrary magnitude. In many cases there is no dispersion equation ("NDE medium") to restrict the wave vector in an EME medium. Attention is paid to the case where the two medium dyadics have the same set of eigenvectors. In such a case the k vector is restricted to three eigenplanes defined by the medium dyadics. The emergence of such a result is demonstrated by considering a more regular medium, and taking the limit of zero permittivity and permeability. The special case of uniaxial EME medium is studied in detail. It is shown that an interface of a uniaxial EME medium appears as a DB boundary when the axis of the medium is normal to the interface. More in general, EME media display interesting wave effects that can potentially be realized through metasurface engineering.arXiv:1604.04416v1 [physics.optics]

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Characterisation and representation of non-dissipative electromagnetic medium with two Lorentz null cones

Cited by 8 publications

References 37 publications

Electromagnetic potential in pre-metric electrodynamics: Causal structure, propagators and quantization

Electromagnetic potential in pre-metric electrodynamics: Causal structure, propagators and quantization

Electromagnetic wave propagation in metamaterials: A visual guide to Fresnel-Kummer surfaces and their singular points

Plane wave propagation in extreme magnetoelectric (EME) medium

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