The chemical evolution of the dwarf spheroidal galaxy Sextans

We present our analysis of the FLAMES dataset targeting the central 25 ' region of the Sextans dwarf spheroidal galaxy (dSph). This dataset is the third major part of the high-resolution spectroscopic section of the ESO large program 171.B-0588(A) obtained by the Dwarf galaxy Abundances and Radial-velocities Team. Our sample is composed of red giant branch stars down to V similar to 20.5 mag, the level of the horizontal branch in Sextans, and allows users to address questions related to both stellar nucleosynthesis and galaxy evolution. We provide metallicities for 81 stars, which cover the wide [Fe/H] = -3.2 to -1.5 dex range. The abundances of ten other elements are derived: Mg, Ca, Ti, Sc, Cr, Mn, Co, Ni, Ba, and Eu. Despite its small mass, Sextans is a chemically evolved system, showing evidence of a contribution from core-collapse and Type Ia supernovae as well as low-metallicity asymptotic giant branch stars (AGBs). This new FLAMES sample offers a sufficiently large number of stars with chemical abundances derived with high accuracy to firmly establish the existence of a plateau in [alpha/Fe] at similar to 0.4 dex followed by a decrease above [Fe/H] similar to -2 dex. These features reveal a close similarity with the Fornax and Sculptor dSphs despite their very different masses and star formation histories, suggesting that these three galaxies had very similar star formation efficiencies in their early formation phases, probably driven by the early accretion of smaller galactic fragments, until the UV-background heating impacted them in different ways. The parallel between the Sculptor and Sextans dSph is also striking when considering Ba and Eu. The same chemical trends can be seen in the metallicity region common to both galaxies, implying similar fractions of SNeIa and low-metallicity AGBs. Finally, as to the iron-peak elements, the decline of [Co/Fe] and [Ni/Fe] above [Fe/H] similar to -2 implies that the production yields of Ni and Co in SNeIa are lower than that of Fe. The decrease in [Ni/Fe] favours models of SNeIa based on the explosion of double-degenerate sub-Chandrasekhar mass white dwarfs.

The last stages of star formation in the dwarf spheroidal galaxy Sextans

Romaine Theler

This thesis is anchored in the research of better understanding of the chemical evolution of galaxies. Many dwarf spheroidal galaxies (dSph) are orbiting the Milky Way displaying various star formation histories. The formation of these dwarf galaxies and the drivers of their evolution are still not well understood. We studied in detail one of them, Sextans, a low mass dSph composed of an old population. 90% of Sextans stars were formed 11-14 Gyr ago (Lee et al. 2009). Battaglia et al. (2011) show the presence of a radial metallicity gradient in Sextans considering observation based on intermediate resolution spectroscopy until the tidal radius. For a projected radius R < 0.8 deg stars cover the whole range of [Fe/H], while for R > 0.8 deg all stars are metal-poor [Fe/H] < -2.2 dex. Due to its distance and its low surface brightness high resolution spectra are required to obtain accurate abundances. Up to recently only 14 Sextans stars have been observed in high resolution spectroscopy (Shetrone et al. 2001; Aoki et al. 2009; Tafelmeyer et al. 2010; Honda et al. 2011) but in majority they were focused only on extremely metal-poor stars. In order to understand the chemical evolution of Sextans we needed to study a statistically significant sample of stars covering a larger metallicity range. This has been done in this work based on the largest high resolution spectroscopic sample of 87 red giant branch stars ever obtained in such low mass dwarf spheroidal galaxies. Our sample of stars located in the center of Sextans displays a large metallicity distribution ranging from -1.0 dex to -3.5 dex. We derived abundances of 10 elements : 3 alpha-elements (Mg, Ca and Ti), 5 iron-peak elements (Sc, Cr,Mn, Co and Ni) and 2 neutron-capture elements (Ba and Eu). Combining the results we had the first picture of the chemical evolution of Sextans. From [alpha/Fe] distribution reflecting the ratio between supernovae [SNe II/SNe Ia], we found that the domination of SNeIa in chemical evolution occurred around [Fe/H] = -2.0 dex. A lower knee than for Fornax and Sculptor suggests that star formation was less efficient in Sextans in agreement with their respective estimated mass. The absence of intrinsic scatter in [alpha/Fe] showed that in the center of Sextans the interstellar medium has been homogeneously enriched through star formation. Some hypothesis like tidal interactions with the Milky Way could explain this abundance homogeneity in the center of the galaxy and the metallicity gradient toward the outskirts. Abundances in iron-peak elements and neutron-capture elements give new observational constraints for a better understanding of the various nucleosynthesis sources of these elements.

EPFL2015

Dwarf Galaxies and Galaxy Halos

Martin Tafelmeyer

The various projects presented in this thesis contribute to the expansion of our knowledge and understanding of the fundamental processes involved in the formation of a galaxy and its stellar populations. For this purpose, two different techniques are applied: A photometric study of the properties of the stellar halo surrounding the edge-on galaxy NGC 3957, and spectroscopic studies of the chemical compositions of stars in the nearby dwarf spheroidal galaxies Sextans, Fornax, and Sculptor. Due to their extreme weakness, studies of halos outside the Local Group are very challenging, and available data are still very scarce with limited quality. The results of previous studies are quite puzzling. Lequeux et al. (1996, 1998); Zibetti et al. (2004); Zibetti & Ferguson (2004), for example, report the discovery of external stellar halos with extremely red integrated colors, which were neither in agreement with the halo stars observed in the Milky Way or M31, nor with any other realistic stellar population. To investigate this problem, we obtained deep images of the edge-on galaxy NGC 3957, to extract minor axis surface brightness profiles, allowing the study of the halo properties in regions which are not contaminated by the much brighter disk or bulge component. While the central regions of our profiles are very well described by a de Vaucouleurs law, we find a clear excess of light at larger radii, indicating the presence of a stellar halo. Our color profiles rise to very red colors at large radii, however, a careful error analysis shows that systematic errors are mainly responsible for this rise. In the radial range where the halo component is dominant and the systematics are still small, our results are compatible with the expected integrated halo colors of the Milky Way, M31 and the slightly more distant galaxy NGC 891. Even though this is no proof, it suggests that the stellar population of the halo of NGC 3957 is a rather typical one. It is shown that the limiting factor is definitely a sufficiently accurate determination of the background level. We propose a few ways how this could be improved. Nevertheless, the sky subtraction remains the largest challenge for future studies of this type, especially if the goal is to trace the stellar halo to larger radii, comparable to the halo of the Milky Way or M31. The targets for the spectroscopic analysis of stars in dwarf galaxies were selected from an extended low resolution survey of the Ca II triplet (CaT) region, containing ∼2000 stars in Sextans, Sculptor, and Fornax. This is the largest survey of this kind done so far targeting stars outside the Milky Way. One of the most striking results of this survey was the absence of stars with metallicity estimations from the strength of the CaT lines which were below -2.8 (Helmi, 2006). This is particularly interesting, since the Milky Way halo contains a wealth of stars clearly below this limit (Cayrel et al., 2004). Such a difference would have consequences for our understanding of galaxy formation, implying that at early epochs dwarf galaxies must have been fundamentally different from the Milky Way halo. However, in some of the recently discovered, so called "ultra faint dwarfs" (UFDs) several stars with very low metallicities ([Fe/H] ∼ -4) have been found (Norris et al., 2009; Kirby et al., 2008; Frebel et al., 2010, 2009). It is therefore essential to test the reliability of the CaT metallicity estimate and confirm or disprove the existence of extremely metal poor stars in classical dwarf spheroidal galaxies (dSphs). For this purpose, the stars with the lowest CaT metallicities were followed up with high resolution spectroscopy in order to accurately determine metallicities and abundances of several other elements. Our analysis shows unambiguously, that these stars are more metal poor than suggested by the CaT estimations, setting the metallicity floor of dwarf galaxies on a level comparable with the Milky Way halo. The chemical abundance patterns of these stars and their comparison with various other dwarf galaxies and the Milky Way provide valuable insights in the earliest chemical enrichment processes. For carbon, we find signs of a large abundance scatter in Sextans, indicating inhomogeneities in the early ISM of this galaxy. Most of the other elements, in contrast, have very small abundance spreads, implying that there must be a specific process leading to a dispersion in carbon abundances. We also find evidence, that the abundance spread is larger for low mass galaxies, indicating that mixing processes in such systems are less efficient. Below [Fe/H] = -3, the abundances of the α- and iron peak elements are very similar in all galaxies, suggesting formation mechanisms independent on the properties of the host galaxy. Other elements show a more ambiguous picture. The neutron-capture elements strontium and barium are similar in all galaxies at the lowest metallicities ([Fe/H] ≲ -3.5). At higher metallicities, however, the more massive galaxies like Sculptor or the Milky Way increase their abundances to solar values (though with some scatter), while the less massive ones like Ursa Major II or Draco stay very low both in [Ba/Fe] and [Sr/Fe]. This is another indication for different chemical evolution, depending on the size of the host galaxy. It shows the importance of studying stars in various galaxies, spanning a large range of masses. Additionally, abundance patterns for a large sample of stars in the Sextans dSph were derived. Previous spectroscopic studies include only a very small number of objects owing to the large observation times required to obtain the spectra, star by star, with single slit spectrographs. This thesis utilizes the multi-object spectrograph GIRAFFE to obtain spectra of a large number of stars simultaneously, allowing us to study chemical abundances for the biggest sample of Sextans stars observed so far. Our targets, which are complemented with literature data, span a metallicity range from -1 to -3, covering different stages of the the chemical evolution history of Sextans. We find that the decrease in [α/Fe] starts at very low metallicities ([Fe/H] ≲ -2), confirming the low star formation rate of Sextans (e.g. Revaz et al., 2009). Comparing our results with other galaxies, some elements (e.g. those of the Fe-peak) have virtually the same abundance patterns everywhere. Others show signs of differential evolution in the metallicity range -1 to -2. One example is Mg, which decreases to lower values in Sextans than in the more massive Sculptor dSph or the Milky Way. Another one is the abundance ratio of 2nd to 1st s-process elements ([Ba/Y]) which is higher in low mass systems such as Sextans and draco than in Sculptor or the Milky Way.

EPFL2010

Manganese in dwarf spheroidal galaxies

Pascale Jablonka, Pierre North

We provide manganese abundances (corrected for the effect of the hyperfine structure) for a large number of stars in the dwarf spheroidal galaxies Sculptor and Fornax, and for a smaller number in the Carina and Sextans dSph galaxies. Abundances had already been determined for a number of other elements in these galaxies, including alpha and iron-peak ones, which allowed us to build [Mn/Fe] and [Mn/alpha] versus [Fe/H] diagrams. The Mn abundances imply sub-solar [Mn/Fe] ratios for the stars in all four galaxies examined. In Sculptor, [Mn/Fe] stays roughly constant between [Fe/H] similar to -1.8 and -1.4 and decreases at higher iron abundance. In Fornax, [Mn/Fe] does not vary in any significant way with [Fe/H]. The relation between [Mn/alpha] and [Fe/H] for the dSph galaxies is clearly systematically offset from that for the Milky Way, which reflects the different star formation histories of the respective galaxies. The [Mn/alpha] behavior can be interpreted as a result of the metal-dependent Mn yields of Type II and Type Ia supernovae. We also computed chemical evolution models for star formation histories matching those determined empirically for Sculptor, Fornax, and Carina, and for the Mn yields of SNe Ia, which were assumed to be either constant or variable with metallicity. The observed [Mn/Fe] versus [Fe/H] relation in Sculptor, Fornax, and Carina can be reproduced only by the chemical evolution models that include a metallicity-dependent Mn yield from the SNe Ia.