English

Color Bimodality in M87 Globular Clusters

Astrophysics 2011-02-11 v1

Abstract

We present an analysis of a 50 orbit HST ACS observation of the M87 globular cluster system. We use the extraordinary depth of this dataset to test whether the colors and magnitudes show evidence for a mass-metallicity relation in globular cluster populations. We find only a weak or absent relation between the colors and magnitudes of the metal poor subpopulation of globular clusters. The weakness or absence of a color-magnitude relation is established over a wide range in luminosity from MV=11M_V=-11 to MV=6M_V=-6, encompassing most of the M87 globular clusters. The constancy of the colors of the metal-poor subpopulation seen in our 50 orbit observation is in contrast to suggestions from single orbit ACS data that the metal-poor globular clusters in M87 and several other galaxies show a "blue tilt." The formal best fit for the mass-metallicity relation for the metal-poor subpopulation in our much deeper data is ZM0.08±0.05Z\propto M^{0.08\pm0.05}. Our analysis of these data also shows a possible small "red tilt" in the metal-rich globular cluster subpopulation. While either of these small tilts may be real, they may also illustrate the limit to which mass-metallicity relations can be determined, even in such extraordinarily deep data. We specifically test for a wide range of systematic effects and find that while small tilts cannot be confirmed or rejected, the data place a strong upper limit to any tilt of 0.20±0.05|0.20|\pm0.05. This upper limit is much smaller than some earlier claims from single orbit data, and strongly limits self-enrichment within globular clusters. This mass-metallicity relation for globular clusters is also shallower than the relation for galaxies, suggesting that the formation mechanisms for these two types of objects are different.

Keywords

Cite

@article{arxiv.0811.0391,
  title  = {Color Bimodality in M87 Globular Clusters},
  author = {Christopher Z. Waters and Stephen E. Zepf and Tod R. Lauer and Edward A. Baltz},
  journal= {arXiv preprint arXiv:0811.0391},
  year   = {2011}
}

Comments

25 pages, 3 figures. Accepted for publication in the Astrophysical Journal

R2 v1 2026-06-21T11:37:49.221Z