Cover Image

Shear-flexion cross-talk in weak-lensing measurements

Show other versions (1)

Gravitational flexion, caused by derivatives of the gravitational tidal field, is potentially important for the analysis of the dark-matter distribution in gravitational lenses, such as galaxy clusters or the dark-matter haloes of galaxies. Flexion estimates rely on measurements of galaxy-shape dist...

Full description

Saved in:
Bibliographic Details
Main Authors: Viola, Massimo (Author) , Melchior, Peter (Author) , Bartelmann, Matthias (Author)
Format: Article (Journal) Chapter/Article
Language:English
Published: 22 Sep 2011
In: Arxiv

Online Access:Verlag, kostenfrei, Volltext: http://arxiv.org/abs/1107.3920
Get full text
Author Notes:Massimo Viola, Peter Melchior, Matthias Bartelmann
Description
Summary:Gravitational flexion, caused by derivatives of the gravitational tidal field, is potentially important for the analysis of the dark-matter distribution in gravitational lenses, such as galaxy clusters or the dark-matter haloes of galaxies. Flexion estimates rely on measurements of galaxy-shape distortions with spin-1 and spin-3 symmetry. We show in this paper that and how such distortions are generally caused not only by the flexion itself, but also by coupling terms of the form (shear $\times$ flexion), which have hitherto been neglected. Similar coupling terms occur between intrinsic galaxy ellipticities and the flexion. We show, by means of numerical tests, that neglecting these terms can introduce biases of up to 85% on the $F$ flexion and 150% on the $G$ flexion for galaxies with an intrinsic ellipticity dispersion of $\sigma_{\epsilon}=0.3$. In general, this bias depends on the strength of the lensing fields, the ellipticity dispersion, and the concentration of the lensed galaxies. We derive a new set of equations relating the measured spin-1 and spin-3 distortions to the lensing fields up to first order in the shear, the flexion, the product of shear and flexion, and the morphological properties of the galaxy sample. We show that this new description is accurate with a bias $\leq 7%$ (spin-1 distortion) and $\leq 3%$ (spin-3 distortion) even close to points where the flexion approach breaks down due to merging of multiple images. We propose an explanation why a spin-3 signal could not be measured yet and comment on the difficulties in using a model-fitting approach to measure the flexion signal.
Item Description:Gesehen am 22.09.2017
Physical Description:Online Resource

Similar Items