Linear pre-metric electrodynamics and deduction of the light cone

Rubilar, Guillermo F.

doi:10.1002/1521-3889(200211)11:10/11<717::aid-andp717>3.0.co;2-6

Cited by 53 publications

(107 citation statements)

References 66 publications

(247 reference statements)

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“…For our simple example of a Klein-Gordon field on a metric geometry, the determinant in (2) is of weight zero, and for the choice ρ = 1 we obtain P i 1 i 2 = G i 1 i 2 , and one indeed recovers the familiar massless dispersion relation G a 1 a 2 k a 1 k a 2 = 0. An instructive non-metric example is provided by abelian gauge theory coupled to an inverse area metric tensor geometry [11,12], which is based on a fourth rank contravariant tensor field G featuring the algebraic symmetries G abcd = G cdab = −G bacd ; calculation of the principal polynomial (after removing gauge-invariance, observing resulting constraints on initial conditions and re-covariantizing the expression) one obtains [10,13,14] in dim M = d dimensions the totally symmetric tensor field…”

Section: A Primer On Tensorial Spacetime Geometriesmentioning

confidence: 99%

Gravitational dynamics for all tensorial spacetimes carrying predictive, interpretable, and quantizable matter

et al. 2012

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Only a severely restricted class of tensor fields can provide classical spacetime geometries, namely those that can carry matter field equations that are predictive, interpretable and quantizable. These three conditions on matter translate into three corresponding algebraic conditions on the underlying tensorial geometry, namely to be hyperbolic, time-orientable and energy-distinguishing. Lorentzian metrics, on which general relativity and the standard model of particle physics are built, present just the simplest tensorial spacetime geometry satisfying these conditions. The problem of finding gravitational dynamics-for the general tensorial spacetime geometries satisfying the above minimum requirements-is reformulated in this paper as a system of linear partial differential equations, in the sense that their solutions yield the actions governing the corresponding spacetime geometry. Thus the search for modified gravitational dynamics is reduced to a clear mathematical task.

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Section: A Primer On Tensorial Spacetime Geometriesmentioning

confidence: 99%

Gravitational dynamics for all tensorial spacetimes carrying predictive, interpretable, and quantizable matter

et al. 2012

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“…The skewon contributions in (24) and (25) are responsible for the electric and magnetic Faraday effects, respectively, whereas skewon terms in (26) and (27) describe optical activity.…”

Section: General Local and Linear Constitutive Relationmentioning

confidence: 99%

“…Here we briefly summarize the results of previous work [6,22,26,27]. In the Hadamard approach, one studies the propagation of a discontinuity in the first derivative of the electromagnetic field.…”

Section: General Fresnel Equations: Wave and Ray Surfacesmentioning

confidence: 99%

Possible skewon effects on light propagation

Obukhov

Hehl

2004

Phys. Rev. D

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We start from a local and linear spacetime relation between the electromagnetic excitation and the field strength. Then we study the generally covariant Fresnel surfaces for light rays and light waves. The metric and the connection of spacetime are left unspecified. Accordingly, our framework is ideally suited for a search of possible violations of the Lorentz symmetry in the photon sector of the extended standard model. We discuss how the skewon part of the constitutive tensor, if suitably parametrized, influences the Fresnel surfaces and disturbs the light cones of vacuum electrodynamics. Conditions are specified that yield the reduction of the original quartic Fresnel surface to the double light cone structure (birefringence) and to the single light cone.Qualitatively, the effects of the real skewon field can be compared to those in absorbing material media. In contrast, the imaginary skewon field can be interpreted in terms of non-absorbing media with natural optical activity and Faraday effects. The astrophysical data on gamma-ray bursts are used for deriving an upper limit for the magnitude of the skewon field.

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“…We have shown in the past (see [13,14]) how one can determine light propagation in an arbitrary spacetime by means of a generalized Fresnel equation provided a linear spacetime relation H = κ(F ), or in components H αβ = 1 2 κ αβ γδ F γδ , is specified. Recently, we applied this method also to nonlinear electrodynamics, see [15].…”

Section: Birefringence For An Arbitrary Spherically Symmetric Tomentioning

confidence: 99%

Torsion nonminimally coupled to the electromagnetic field and birefringence

Rubilar¹,

Obukhov²,

Hehl³

2003

Class. Quantum Grav.

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In conventional Maxwell-Lorentz electrodynamics, the propagation of light is influenced by the metric, not, however, by the possible presence of a torsion T . Still the light can feel torsion if the latter is coupled nonminimally to the electromagnetic field F by means of a supplementary Lagrangian of the type ∼ ℓ 2 T 2 F 2 (ℓ = coupling constant). Recently Preuss suggested a specific nonminimal term of this nature. We evaluate the spacetime relation of Preuss in the background of a general O(3)-symmetric torsion field and prove by specifying the optical metric of spacetime that this can yield birefringence in vacuum. Moreover, we show that the nonminimally coupled homogeneous and isotropic torsion field in a Friedmann cosmos affects the speed of light.

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Linear pre-metric electrodynamics and deduction of the light cone

Cited by 53 publications

References 66 publications

Gravitational dynamics for all tensorial spacetimes carrying predictive, interpretable, and quantizable matter

Gravitational dynamics for all tensorial spacetimes carrying predictive, interpretable, and quantizable matter

Possible skewon effects on light propagation

Torsion nonminimally coupled to the electromagnetic field and birefringence

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