Casimir effect between ponderable media as modeled by the standard model extension

The CPT-even sector of the standard model extension amounts to extending Maxwell electrodynamics by a gauge invariant term of the form −14(kF)αβμνFαβFμν, where the Lorentz-violating (LV) background tensor (kF)αβμν possesses the symmetries of the Riemann tensor. The electrodynamics in ponderable medi...

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Bibliographic Details
Published in:Physical review. D 2016-10, Vol.94 (7), Article 076010
Main Authors: Martín-Ruiz, A., Escobar, C. A.
Format: Article
Language:English
Subjects:
Coefficients
Constitutive relationships
Electrodynamics
Flux density
Mathematical models
Maxwell's equations
Tensors
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Summary:The CPT-even sector of the standard model extension amounts to extending Maxwell electrodynamics by a gauge invariant term of the form −14(kF)αβμνFαβFμν, where the Lorentz-violating (LV) background tensor (kF)αβμν possesses the symmetries of the Riemann tensor. The electrodynamics in ponderable media is still described by Maxwell equations in matter with modified constitutive relations which depend on the coefficients for Lorentz violation. We study the effects of this theory on the Casimir force between two semi-infinite ponderable media. The Fresnel coefficients characterizing the vacuum-medium interface are derived, and with the help of these, we compute the Casimir energy density. At leading order in the LV coefficients, the Casimir energy density is numerically evaluated and successfully compared with the standard result. We also found a variety of intriguing effects, such as a nontrivial Kerr effect and the Casimir effect between two phases of the electromagnetic vacuum. We consider a bubble of Lorentz-symmetric (Maxwell) vacuum embedded in the infinite Lorentz-violating vacuum, and we calculate the Casimir energy at leading order, which in this case is quadratic in the LV coefficients. The Casimir force can be positive, zero, or negative, depending on the relative strengths between the LV coefficients.
ISSN:2470-0010
2470-0029
DOI:10.1103/PhysRevD.94.076010