Weyl–Dirac theory predictions on galactic scales

Weyl–Dirac theory predictions on galactic scales

We consider the Weyl–Dirac theory within the framework of the weak field approximation and show that the resulting gravitational potential differs from that of Newtonian by a repulsive correction term increasing with distance. The scale of the correction term appears to be determined by the time var...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society Vol. 385; no. 2; pp. 986 - 994
Main Authors: Mirabotalebi, S., Jalalzadeh, S., Movahed, M. Sadegh, Sepangi, H. R.
Format: Journal Article
Language:English
Published: Oxford, UK Blackwell Publishing Ltd 01-04-2008
Blackwell Science
Oxford University Press
Subjects:
Astronomy
Astrophysics
Earth, ocean, space
Exact sciences and technology
galaxies: fundamental parameters
galaxies: spiral
gravitation
gravitational lensing
Gravity
Normal distribution
Stars & galaxies
Theory
gravitational lensing
galaxies: fundamental parameters
gravitation
galaxies: spiral
Dirac theory
Gravitation
Rotation curve
Consistency
Gravitational lensing
Weyl theory
Time variation
Galaxy clusters
Gravitational potential
Theoretical model
Dark matter
Spiral galaxies
Corrections
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Summary:We consider the Weyl–Dirac theory within the framework of the weak field approximation and show that the resulting gravitational potential differs from that of Newtonian by a repulsive correction term increasing with distance. The scale of the correction term appears to be determined by the time variation rate of the gravitational coupling. It is shown that if the time variation rate of gravitational coupling is adopted from observational bounds, the theory can explain the rotation curves of typical spiral galaxies without resorting to dark matter. To check the consistency of our theoretical model with observation we use likelihood analysis to find the best-fitting values for the free parameters. The mean value for the most important free parameter, β× 1014 (yr−1), using the top-hat and Gaussian priors are 6.38+2.44−3.46+6.18−6.71 and 5.72+1.22−1.18+2.90−2.69, respectively. Although the interval for which β is defined is wide, our results show that the goodness of the fit is, by and large, not sensitive to this quantity. The intergalactic effects and gravitational lensing of clusters of galaxies are estimated and seem to be consistent with observational data.
Bibliography:istex:63BD55583ACA7D7C4212544814966B119E7C1552
ark:/67375/HXZ-GN7WHSMB-R
ISSN:0035-8711
1365-2966
DOI:10.1111/j.1365-2966.2008.12904.x