Quantifying dwarf satellites through gravitational imaging: the case of SDSS J120602.09+514229.5

TL;DR

This paper demonstrates a Bayesian gravitational lens modeling method to detect and measure the mass of a dwarf satellite galaxy at high redshift, revealing its properties through pixelized lensing techniques.

Contribution

The study introduces a grid-based Bayesian lens modeling approach capable of detecting galactic satellites independently of their mass-to-light ratio at high redshift.

Findings

Detected a luminous satellite with mass (2.75±0.04)×10^10 M_sun

Measured the satellite's luminosity as (1.6±0.8)×10^9 L_sun

Derived the satellite's mass-to-light ratio as (17.2±8.5) M_sun/L_sun

Abstract

SDSS J120602.09+514229.5 is a gravitational lens system formed by a group of galaxies at redshift z=0.422 lensing a bright background galaxy at redshift z=2.001. The main peculiarity of this system is the presence of a luminous satellite near the Einstein radius, that slightly deforms the giant arc. This makes SDSS J120602.09+514229.5 the ideal system to test our grid-based Bayesian lens modelling method, designed to detect galactic satellites independently from their mass-to-light ratio, and to measure the mass of this dwarf galaxy despite its high redshift. Thanks to the pixelized source and potential reconstruction technique of Vegetti and Koopmans 2009a we are able to detect the luminous satellite as a local positive surface density correction to the overall smooth potential. Assuming a truncated Pseudo-Jaffe density profile, the satellite has a mass M=(2.75+-0.04)10^10 M_sun inside its tidal radius of r_t=0.68". We determine for the satellite a luminosity of L_B=(1.6+-0.8)10^9 L_sun, leading to a total mass-to-light ratio within the tidal radius of (M/L)_B=(17.2+-8.5) M_sun/L_sun. The central galaxy has a sub-isothermal density profile as in general is expected for group members. From the SDSS spectrum we derive for the central galaxy a velocity dispersion of sigma_kinem=380+-60 km/s within the SDSS aperture of diameter 3". The logarithmic density slope of gamma=1.7+0.25-0.30 (68% CL), derived from this measurement, is consistent within 1-sigma with the density slope of the dominant lens galaxy gamma~1.6, determined from the lens model. This paper shows how powerful pixelized lensing techniques are in detecting and constraining the properties of dwarf satellites at high redshift.