Multi-Epoch HST Observations of IZw18: Characterization of Variable Stars at Ultra-Low Metallicities

TL;DR

This study identifies and analyzes variable stars, including the lowest metallicity Classical Cepheids, in the ultra-metal-poor galaxy IZw18, providing new insights into stellar pulsation and galaxy distance measurement at extreme metallicities.

Contribution

First detection of variable stars in IZw18, including the lowest metallicity Classical Cepheids, and application of pulsation models to estimate galaxy distance at ultra-low metallicity.

Findings

Identified 34 variable stars, including 3 Classical Cepheids.

Estimated galaxy distance of approximately 19 Mpc using pulsation models.

Confirmed consistency between pulsation-based and TRGB distance measurements.

Abstract

Variable stars have been identified for the first time in the very metal-poor Blue Compact dwarf galaxy IZw18, using deep multi-band (F606W, F814W)time-series photometry obtained with the Advanced Camera for Surveys (ACS) on board the Hubble Space Telescope (HST). We detected 34 candidate variable stars in the galaxy. We classify three of them as Classical Cepheids, with periods of 8.71, 125.0 and 130.3 days, respectively, and other two as long period variables with periodicities longer than a hundred days. These are the lowest metallicity Classical Cepheids known so far, thus providing the opportunity to explore and fit models of stellar pulsation fo Classical Cepheids at previously inaccessible metallicities. The period distribution of the confirmed Cepheids is markedly different from what is seen in other nearby galaxies, which is likely related to the star bursting nature of IZw18. By applying to the 8.71 days Cepheid theoretical Wesenheit (V,I) relations based on new pulsation models of Classical Cepheids specifically computed for the extremely low metallicity of this galaxy (Z=0.0004, Y=0.24), we estimate the distance modulus of IZw18 to be mu_0= 31.4pm0.2 D=19.0^{+1.8}_{-1.7}Mpc) for canonical models of Classical Cepheids, and of 31.2pm0.2 mag (D=17.4^{+1.6}_{-1.6}Mpc) using over luminous models. The theoretical modeling of the star's light curves provides mu_0=31.4pm0.1 mag, D=19.0^{+0.9}_{-0.9} Mpc, in good agreement with the results from the theoretical Wesenheit relations. These pulsation distances bracket the distance of 18.2pm1.5Mpc inferred by Aloisi et al. (2007) using the galaxy's Red Giant Branch Tip.