Linear pre‐metric electrodynamics and deduction of the light cone

Rubilar, Guillermo F.

doi:10.1002/andp.200251410-1102

Cited by 5 publications

(2 citation statements)

References 63 publications

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“…For scalar permittivity and permeability, this gives the compatibility condition ϵ = µ of the above quote from Landau and Lifshitz [5]. The tensorial generalization to ϵ ij = µ ij was then rederived several times in the literature with different inspirations [16,45,46]. Even the most general cases can always (at least locally) be reduced to this case by appropriate frame changes [1].…”

Section: General Strategymentioning

confidence: 99%

Boyer–Lindquist Space-Times and Beyond: Metamaterial Analogues for Arbitrary Space-Times

Schuster,

Visser

2024

Universe

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Analogue space-times (and in particular metamaterial analogue space-times) have a long varied and rather complex history. Much of the previous related work to this field has focused on spherically symmetric models; however, axial symmetry is much more relevant for mimicking astrophysically interesting systems that are typically subject to rotation. Now it is well known that physically reasonable stationary axisymmetric space-times can, under very mild technical conditions, be put into Boyer–Lindquist form. Unfortunately, a metric presented in Boyer–Lindquist form is not well adapted to the “quasi-Cartesian” metamaterial analysis that we developed in our previous articles on “bespoke analogue space-times”. In the current article, we shall first focus specifically on various space-time metrics presented in Boyer–Lindquist form, and subsequently determine a suitable set of equivalent metamaterial susceptibility tensors in a laboratory setting. We shall then turn to analyzing generic space-times, not even necessarily stationary, again determining a suitable set of equivalent metamaterial susceptibility tensors. Perhaps surprisingly, we find that the well-known ADM formalism proves to be not particularly useful, and that it is instead the dual “threaded” (Kaluza–Klein–inspired) formalism that provides much more tractable results. While the background laboratory metric is (for mathematical simplicity and physical plausibility) always taken to be Riemann flat, we will allow for arbitrary curvilinear coordinate systems on the flat background space-time. Finally, for completeness, we shall reconsider spherically symmetric space-times, but now in general spherical polar coordinates rather than quasi-Cartesian coordinates. In summary, this article provides a set of general-purpose calculational tools that can readily be adapted for mimicking various interesting (curved) space-times by using nontrivial susceptibility tensors in general (background-flat) laboratory settings.

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Section: General Strategymentioning

confidence: 99%

Boyer–Lindquist Space-Times and Beyond: Metamaterial Analogues for Arbitrary Space-Times

Schuster,

Visser

2024

Universe

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“…This quantum interaction would become manifest in a dispersion relation which is close to that given by GR at low energies, but exhibits larger deviations at higher energies. Commonly studied example of MDRs include models derived from doubly or deformed special relativity (DSR) [9][10][11], more generally deformed relativistic kinematics [12][13][14][15], non-commutative spacetime geometries [16][17][18][19], string theory [20,21], loop quantum gravity [22][23][24][25], the Standard-Model Extension (SME) [26], as well as the propagation of fields through media [27][28][29][30][31][32][33][34].…”

Section: Introductionmentioning

confidence: 99%

Kinetic gases in static spherically symmetric modified dispersion relations

Hohmann

2023

Class. Quantum Grav.

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We study the dynamics of a collisionless kinetic gas in the most general static, spherically symmetric dispersion relation. For a static, spherically symmetric kinetic gas, we derive the most general solution to these dynamics, and find that any solution is given by a one-particle distribution function which depends on three variables. For two particular solutions, describing a shell of monoenergetic orbiting particles and a purely radial inflow, we calculate the particle density as a function of the radial coordinate. As a particular example, we study aκ-Poincaré modification of the Schwarzschild metric dispersion relation and derive its influence on the particle density. Our results provide a possible route towards quantum gravity phenomenology via the observation of matter dynamics in the vicinity of massive compact objects.

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