# The inner dark matter distribution of the Cosmic Horseshoe (J1148+1930)   with gravitational lensing and dynamics

**Authors:** S. Schuldt, G. Chiriv\`i, S. H. Suyu, A. Y{\i}ld{\i}r{\i}m, A., Sonnenfeld, A. Halkola, G. F. Lewis

arXiv: 1901.02896 · 2019-10-23

## TL;DR

This study combines gravitational lensing and dynamical modeling to analyze the inner dark matter distribution of the Cosmic Horseshoe galaxy, revealing a high dark matter fraction and demonstrating the radial arc's role in constraining dark matter profiles.

## Contribution

It introduces a comprehensive method integrating lensing and stellar dynamics to determine dark matter distribution, independent of dark matter profile assumptions.

## Key findings

- Dark matter fraction between 60% and 70%.
- Radial arc constrains inner dark matter profile independently.
- Model fits well across different dark matter profiles.

## Abstract

We present a detailed analysis of the inner mass structure of the Cosmic Horseshoe (J1148+1930) strong gravitational lens system observed with the Hubble Space Telescope (HST) Wide Field Camera 3 (WFC3). In addition to the spectacular Einstein ring, this systems shows a radial arc. We obtained the redshift of the radial arc counter image $z_\text{s,r} = 1.961 \pm 0.001$ from Gemini observations. To disentangle the dark and luminous matter, we consider three different profiles for the dark matter distribution: a power-law profile, the NFW, and a generalized version of the NFW profile. For the luminous matter distribution, we base it on the observed light distribution that is fitted with three components: a point mass for the central light component resembling an active galactic nucleus, and the remaining two extended light components scaled by a constant M/L. To constrain the model further, we include published velocity dispersion measurements of the lens galaxy and perform a self-consistent lensing and axisymmetric Jeans dynamical modeling. Our model fits well to the observations including the radial arc, independent of the dark matter profile. Depending on the dark matter profile, we get a dark matter fraction between 60 % and 70 %. With our composite mass model we find that the radial arc helps to constrain the inner dark matter distribution of the Cosmic Hoseshoe independently of the dark matter profile.

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Source: https://tomesphere.com/paper/1901.02896