Model Color-Magnitude Diagrams for Hubble Space Telescope Observations of Local Group Dwarf Galaxies

Aparicio, A.; Gallart, C.; Chiosi, C.; Bertelli, G.
Bibliographical reference

Astrophysical Journal Letters v.469, p.L97

Advertised on:
10
1996
Number of authors
4
IAC number of authors
2
Citations
46
Refereed citations
33
Description
In this Letter, we discuss a method to conduct a quantitative study of the star formation history (SFH) of Local Group (LG) galaxies using Hubble Space Telescope (HST) data. This method has proved to be successful in the analysis of the SFH of the same kind of galaxies using ground-based observations. It is based on the comparison of observed CMDs with a set of model CMDs. The latter are computed assuming different evolutionary scenarios and include a detailed simulation of observational effects. CMDs obtained with HST are ~3 mag deeper than typical CMDs obtained from ground-based telescopes, allowing the observation, for all LG galaxies, of a part of the CMD that up till now had remained accessible only for the very nearest galaxies. A very important feature that will become accessible with HST is the horizontal branch plus the red clump. The distribution of stars along this structure is quite sensitive to age and metallicity and should provide a very important improvement in the time resolution of the SFH for stars older than ~=2--3 Gyr. We show and discuss four model CMDs that would be comparable with CMDs from deep HST observations. These model CMDs represent the following evolutionary scenarios corresponding to a wide range of dwarf galaxy subtypes from dI to dE: case A, a constant SFR from 15 Gyr ago to the present time; case B, same as case A, but with the SFR stopped 0.5 Gyr ago; case C, a constant SFR in the age range 10--9 Gyr; and case D, same as case C but in the age range 15--12 Gyr. In all four cases a range of metallicity from Z = 0.0001 to Z = 0.004 has been assumed. The present analysis is just a first qualitative approach to what one may expect to find in the CMDs of LG galaxies. However, a complete set of model CMDs must be computed to analyze the data for each galaxy, using the crowding effects derived for that particular galaxy.