Loop quantum gravity and light propagation

A. Ashtekar; A. Ashtekar; A. Ashtekar; A. Ashtekar; A. Ashtekar; A. Ashtekar; A. Ashtekar; A. Ashtekar; A. Ashtekar; A. Ashtekar; A. Corichi; B. Brugmann; C. Rovelli; C. Rovelli; C. Rovelli; C. Rovelli; D. Colladay; D.A.R. Dalvit; D.V. Ahluwalia; E. Waxman; E. Waxman; E. Waxman; F. Benatti; F. Benatti; F. Halzen; G. Amelino-Camelia; G. Amelino-Camelia; G.Z. Adunas; G.Z. Adunas; H. Sahlmann; H. Yu; H.A. Morales-Técotl; Hugo A. Morales-Técotl; J. Alfaro; J. Ellis; J. Ellis; J. Ellis; J. Ellis; J. Ellis; J. Iwasaki; J. Iwasaki; J. van Paradis; J. Zegwaard; J.F. Barbero; J.F. Barbero; J.M. Carmona; J.M. Carmona; Jorge Alfaro; Luis F. Urrutia; M. Bojowald; M. Montesinos; M. Montesinos; M. Varadarajan; M. Varadarajan; M. Varadarajan; M. Vietri; M.L. Metzger; N. Grot; P. Mészáros; P.N. Bhat; R. Borissov; R. Gambini; R.J. Gleiser; T. Jacobson; T. Thiemann; T. Thiemann; T. Thiemann; T. Thiemann; T. Thiemann; T. Thiemann

research

Loop quantum gravity and light propagation

Authors: A. Ashtekar
A. Ashtekar
A. Ashtekar
A. Ashtekar
A. Ashtekar
A. Ashtekar
A. Ashtekar
A. Ashtekar
A. Ashtekar
A. Ashtekar
A. Corichi
B. Brugmann
C. Rovelli
C. Rovelli
C. Rovelli
C. Rovelli
D. Colladay
D.A.R. Dalvit
D.V. Ahluwalia
E. Waxman
E. Waxman
E. Waxman
F. Benatti
F. Benatti
F. Halzen
G. Amelino-Camelia
G. Amelino-Camelia
G.Z. Adunas
G.Z. Adunas
H. Sahlmann
H. Yu
H.A. Morales-Técotl
Hugo A. Morales-Técotl
J. Alfaro
J. Ellis
J. Ellis
J. Ellis
J. Ellis
J. Ellis
J. Iwasaki
J. Iwasaki
J. van Paradis
J. Zegwaard
J.F. Barbero
J.F. Barbero
J.M. Carmona
J.M. Carmona
Jorge Alfaro
Luis F. Urrutia
M. Bojowald
M. Montesinos
M. Montesinos
M. Varadarajan
M. Varadarajan
M. Varadarajan
M. Vietri
M.L. Metzger
N. Grot
P. Mészáros
P.N. Bhat
R. Borissov
R. Gambini
R.J. Gleiser
T. Jacobson
T. Thiemann
T. Thiemann
T. Thiemann
T. Thiemann
T. Thiemann
T. Thiemann
Publication date: 31 January 2002
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Within loop quantum gravity we construct a coarse-grained approximation for the Einstein-Maxwell theory that yields effective Maxwell equations in flat spacetime comprising Planck scale corrections. The corresponding Hamiltonian is defined as the expectation value of the electromagnetic term in the Einstein-Maxwell Hamiltonian constraint, regularized a la Thiemann, with respect to a would-be semiclassical state. The resulting energy dispersion relations entail Planck scale corrections to those in flat spacetime. Both the helicity dependent contribution of Gambini and Pullin [GP] and, for a value of a parameter of our approximation, that of Ellis et. al. [ELLISETAL] are recovered. The electric/magnetic asymmetry in the regularization procedure yields nonlinearities only in the magnetic sector which are briefly discussed. Observations of cosmological Gamma Ray Bursts might eventually lead to the needed accuracy to study some of these quantum gravity effects.Comment: Latex, 45 pages, shorter abstract, additional reference

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