ACS imaging of star clusters in M51 II. The luminosity function and mass function across the disk

TL;DR

This study uses HST/ACS data to analyze the luminosity and mass functions of star clusters in M51, revealing a likely upper mass limit and its variation across the galaxy's disk.

Contribution

It provides evidence for a truncated initial mass function of star clusters in M51 and explores how this limit varies with galactocentric distance.

Findings

The cluster luminosity function is better described by a double power law.

There is likely a physical upper mass limit for star clusters in M51.

Upper mass limit and disruption parameters vary with galactic radius.

Abstract

Whether or not there exists a physical upper mass limit for star clusters is still unclear. HST/ACS data for the rich cluster population in the interacting galaxy M51 enables us to investigate this in more detail. We investigate whether the cluster luminosity function (LF) in M51 shows evidence for an upper limit to the mass function. The variations of the LF parameters with position on the disk are addressed. We determine the cluster LF for all clusters in M51 falling within our selection criteria, as well as for several subsets of the sample. In that way we can determine the properties of the cluster population as a function of galactocentric distance and background intensity. By comparing observed and simulated LFs we can constrain the underlying cluster initial mass function and/or cluster disruption parameters. A physical upper mass limit for star clusters will appear as a bend dividing two power law parts in the LF, if the cluster sample is large enough to sample the full range of cluster masses. The location of the bend in the LF is indicative of the value of the upper mass limit. The slopes of the power laws are an interplay between upper masses, disruption and fading. The LF of the cluster population of M51 is better described by a double power law than by a single power law. We show that the cluster initial mass function is likely to be truncated at the high mass end. We conclude from the variation of the LF parameters with galactocentric distance that both the upper mass limit and the cluster disruption parameters are likely to be a function of position in the galactic disk. At higher galactocentric distances the maximum mass is lower, cluster disruption slower, or both.