Weak gravitational flexion

Flexion is the significant third-order weak gravitational lensing effect responsible for the weakly skewed and arc-like appearance of lensed galaxies. Here we demonstrate how flexion measurements can be used to measure galaxy halo density profiles and large-scale structure on non-linear scales, via...

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Bibliographic Details
Published inMonthly notices of the Royal Astronomical Society Vol. 365; no. 2; pp. 414 - 428
Main Authors Bacon, D. J., Goldberg, D. M., Rowe, B. T. P., Taylor, A. N.
Format Journal Article
LanguageEnglish
Published Oxford, UK Blackwell Science Ltd 01.01.2006
Blackwell Science
Oxford University Press
Subjects
Astronomy
Cosmic rays
Dark matter
Earth, ocean, space
Exact sciences and technology
galaxies: haloes
gravitational lensing
Gravity
large-scale structure of Universe
Stars & galaxies
Galaxy halo
Red shift
Shear
Galaxies
Third order
large-scale structure of Universe
Gravitational lensing
Spheres
Correlation functions
Large-scale structure
Cross correlations
Dark matter
Mapping manifolds
galaxies: haloes
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Summary:Flexion is the significant third-order weak gravitational lensing effect responsible for the weakly skewed and arc-like appearance of lensed galaxies. Here we demonstrate how flexion measurements can be used to measure galaxy halo density profiles and large-scale structure on non-linear scales, via galaxy-galaxy lensing, dark matter mapping and cosmic flexion correlation functions. We describe the origin of gravitational flexion, and discuss its four components, two of which are first described here. We also introduce an efficient complex formalism for all orders of lensing distortion. We proceed to examine the flexion predictions for galaxy-galaxy lensing, examining isothermal sphere and Navarro-Frenk-White (NFW) profiles and both circularly symmetric and elliptical cases. We show that in combination with shear we can precisely measure galaxy masses and NFW halo concentrations. We also show how flexion measurements can be used to reconstruct mass maps in two-dimensional projection on the sky, and in three dimensions in combination with redshift data. Finally, we examine the predictions for cosmic flexion, including convergence-flexion cross-correlations, and we find that the signal is an effective probe of structure on non-linear scales.
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ISSN:0035-8711
1365-2966
DOI:10.1111/j.1365-2966.2005.09624.x