A wide-area view of the Phoenix dwarf galaxy from VLT/FORS imaging

TL;DR

This study provides a comprehensive wide-area photometric analysis of the Phoenix dwarf galaxy, revealing its structural properties, stellar population distribution, and potential evolutionary links between dwarf irregular and spheroidal galaxies.

Contribution

It offers the first detailed wide-area VLT/FORS imaging analysis of Phoenix, characterizing its structure and stellar populations across different ages, supporting the dwarf galaxy evolution hypothesis.

Findings

The galaxy's overall structure fits a Sersic profile with specific parameters.

Younger stars are more centrally concentrated than older stars.

The data confirms the presence of a red giant branch bump.

Abstract

We present results from a wide-area photometric survey of the Phoenix dwarf galaxy, one of the rare dwarf irregular/ dwarf spheroidal transition type galaxies (dTs) of the Local Group (LG). These objects offer the opportunity to study the existence of possible evolutionary links between the late- and early- type LG dwarf galaxies, since the properties of dTs suggest that they may be dwarf irregulars in the process of transforming into dwarf spheroidals. Using FORS at the VLT we have acquired VI photometry of Phoenix. The data reach a S/N~10 just below the horizontal branch of the system and consist of a mosaic of images that covers an area of 26' x 26' centered on the coordinates of the optical center of the galaxy. Examination of the colour-magnitude diagram and luminosity function revealed the presence of a bump above the red clump, consistent with being a red giant branch bump. The deep photometry combined with the large area covered allows us to put on a secure ground the determination of the overall structural properties of the galaxy and to derive the spatial distribution of stars in different evolutionary phases and age ranges, from 0.1 Gyr to the oldest stars. The best-fitting profile to the overall stellar population is a Sersic profile of Sersic radius R_S = 1.82'+-0.06' and m=0.83+-0.03. We confirm that the spatial distribution of stars is found to become more and more centrally concentrated the younger the stellar population, as reported in previous studies. This is similar to the stellar population gradients found for close-by Milky Way dwarf spheroidal galaxies. We quantify such spatial variations by analyzing the surface number density profiles of stellar populations in different age ranges; [Abridged]