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Massive Stars and Star Clusters in the Antennae Galaxies Brad Whitmore 2006, May Workshop Principle Collaborators: - Rupali Chandar - Francois Schweizer - Mike Fall - Qing Zhang - Barry Rothberg OUTLINE • The Formation of Young Massive Clusters • Three Questions about Massive Stars • The Big Picture The Formation of Young Massive Clusters (i.e. Super Star Clusters) • Most stars are formed in groups and clusters, (e.g., Lada & Lada, 2003) • Star formation is enhanced in merging galaxies, and most of the star formation is in the form of young massive clusters. • Hence, understanding what triggers the formation of star clusters in mergers is important for understanding the formation of stars in general. NGC 4038/9 is the youngest and nearest galaxy in the Toomre sequence, hence perhaps our best chance for understanding the formation of massive compact star clusters in mergers. Toomre, “The Evolution of Galaxies and Stellar Populations”, 1977 Are They Really Young Globular Clusters ? Some of the young clusters we see in the Antennae (and other merging galaxies) have the: • Colors (-0.2 < V-I < 0.6) • Luminosities (-15 < Mv < ?, power law LF with index ~ -2) • Sizes (Reff ~ 4 pc) • Distributions (similar to the field stars) • Spectra (~ 10 objects age dated at 3 - 20 Myr) • Velocity Dispersions (10 - 15 km/s) • Masses (104 - 106) to be globular clusters with ages in the range 1 to ~ 500 Myr. Perhaps the most convincing evidence that some clusters will survive to become regular globular clusters is the presence of these ~500 Myr clusters in the NE extension. Three Questions about Massive Stars • What triggers the formation of stars (clusters) ? • What fraction of stars are in clusters, and is this consistent with the idea that essentially all stars form in clusters ? • What can we say about the stellar content of the super star clusters ? What triggers the formation of clusters ? It is clear that shocks are important (e.g., along spirals arms). In mergers, one popular model (e.g., Kumai et al. 1993) is that cloud-cloud collisions with velocities ~ 50 –100 km/s are required. We have used STIS longslit spectra in 3 positions angle of the Antennae to test this idea. Whitmore et al. 2005 We find the the velocity fields are remarkably quiescent. RMS dispersions are ~10 km/sec, essentially the same as in the disks of normal spiral galaxies. This does not favor high velocity cloud-cloud collision models. Instead, models where a high pressure interstellar medium implodes GMCs without greatly altering their initial velocity distribution are favored (e.g, Jog and Solomon, Elmegreen, ….) . What Fraction of Massive Stars in the Antennae are in Clusters? Studies of starburst and merging galaxies find that 10 – 50 % of the UV light (i.e., young stars) are in clusters (Meuer 1995). Whitmore, Chandar & Fall (2006) model (details in big picture part of talk) The initial fraction of stars in clusters is even higher since most clusters don’t survive. Our Antennae model predicts ~ 8 % of the UV luminosity is from clusters, in agreement with observations ( ~10 %). Hence, our data is consistent with the idea that all stars are born in clusters. See Fall, Chandar, Whitmore (2005) for a related calculation using total H_alpha flux. ~ median age of observed clusters Even clusters that survive loose a large fraction of their stars from their outer halos. Whitmore et al. 1999 ~ 50 % of the light is beyond 50 pc in Knot S, a typical tidal radius for a globular cluster. ~ 10 Myr Bastian & Goodwin (2005) find similar profiles in M82, N1569, and N1705, compatible with N-body simulations of clusters with rapid removal of mass due to gas expulsion. Fall, Chandar & Whitmore (2005) make a similar argument to explain the disruption of ~90 % of clusters in the first 10 Myr (infant mortality). ~ 500 Myr Other observations that support this basic picture are: Chandar et al. (2005) find that the integrated spectrum of the field stars in several local starburst galaxies is consistent with formation from clusters which have dissolved, with typical time scales of 7 – 10 Myr. (NOTE: Similar result by Tremonti et al. 2001). Wit et al. (2005) use proper motions from Hipparcus to estimate that only 4 +/- 2 % of the O and B stars in the Milky Way formed outside of groups or clusters • Most of the O and B stars in the field are consistent with being “runaway” stars from nearby groups and clusters. What can we say about the Stellar Component in the Antennae ? In our 1999 paper, one of our primary difficulties was differentiating stars from clusters. This led us to conclude that the number of young star clusters in the Antennae was between 800 and 8000, a pretty big range ! Our new ACS data provides a better opportunity for making this determination, and for studying the stars in their own right. NOTE: This is work in progress, and exploratory in nature. Before starting on the Antennae … Ubeda, Maiz-Appendiaz, and Mackenty (2006) recently completed an impressive piece of work on NGC 4314, a nearby (3 Mpc) starburst dwarf galaxy. Using CHORIOS (publicly available) , a software package they wrote to perform maximum likliehood fits to either clusters or stars, they have taken the game to a new level of sophistication. There main conclusions are: • Extinction is quite patchy, but relatively low around all but the youngest clusters. • 10 of the 12 clusters they study have ages < 10 Myr. • The blue-to-red supergiant ratios are consistent with theory. • The stellar IMF in the field is steeper than –2.8. They isolate 12 apertures (cluster regions) and also individual field stars. They use up to 6 filters (F170, F336W, F555W, F814W, J, H) and make fits assuming bothmost stellar and cluster 1. The massive youngSEDs. clusters in merging galaxies, such as the appear tocontour be excellent They alsoAntennae, make confidence plots. candidates for proto-globular clusters. Examples for region I-As Below is an example of a cluster where 2 individual stars (1 RSG and 1 BSG) within the cluster appear to contribute a significant fraction of the total luminosity. Ubeda et al. (2006) use this example to demonstrate the stochastic nature of low mass clusters, where a single star or two can greatly affect the results. What would 30 Dor (core Mv ~ -10, 10**5 Msolar) look like at the distance of the Antennae? 30 Dor Region S • Is it possible to distinguish clusters from stars just based on a concentration index (i.e., Vmag(3 pix) – Vmag(1 pix))? Conclusions: Past procedure of using Mv < -9 as criteria ( based on Humphreys 1983) to define clusters is ~ 90 % accurate. Using point-like vs. resolved concentration indexes to define stars is only partially successful. (color-color is better). clusters clusters > 50 % of the faint objects are clusters (important !) stars stars Chorizos Fits: if cluster if star • Help distinguish between stars and clusters • Provide estimates of Mbol and Log Te. Radial Profiles • Help distinguish between stars and clusters Some evidence for triggered star cluster formation? Red = greater than 10 Myr Green = 3 – 10 Myr Blue = less than 3 Myr Attempt to make a Mbol vs. Log Te diagram for stars. • Selecting stars based on size or color alone does not work very well. • Using both size and color appears to work pretty well. How far can a runaway O star get? 250 pc (40 km/s for 5 Myr) Maximum runaway O star definition . Wit et al. (2005) Tentative Summary for Exploratory Study of Region S in the Antennae 1. It is possible to study individual stars brighter than Mv = –6 mag in the Antennae (using both “size” and color to differentiate stars from clusters). 2. The brightest (Mv ~ -9.1) and most massive (~100 Msolar) stars around region S are typical of stars found in other environments (e.g., MW, 30 Dor). 3. There is tentative evidence for some triggering of star clusters around Region S. 4. > 50 % of the faint objects with Mv brighter than –9 are clusters. Hence, the total number of clusters in the Antennae is closer to 8000 than 800. (NOTE: Need to sort out color selection effects). Other Studies Comparing Stellar and Cluster Components in External Galaxies. Saviane, Hibbard, Rich (2004) studied the stellar component in the dwarf at the end of the tidal tail in the Antennae. They conclude: • There is a young component of stars with ages 2 – 100 Myr. • No “super star clusters” are present. They suggest that the environment is not conducive to their formation. • They use the tip of the red giant technique to estimate a distance which is ~ 30 % closer than our previous estimate (we believe unlikely since peculiar velocity would have to be ~ 500 km/s). • While there are no Super Star Clusters (i.e., with Mv < -9), many of the point-like objects are clearly resolved clusters. • With this low a rate of star formation we wouldn’t expect a cluster brighter than Mv = -9. The brightest cluster on the PC is Mv = –8.4 (-7.7 if we use their distance), hence only slightly fainter. Statistics not different physics. The Big Picture Roughly 40 gas-rich mergers have now been observed in detail by HST. All show young star clusters. In addition, we find young, massive, compact clusters in: starburst dwarf galaxies (e.g., Meurer et al., 1995), barred galaxies (Barth et al., 1995), spiral galaxies (Larsen & Richtler, 1999) Milky Way and LMC (e.g., Walborn 2000) These clusters have properties similar to those seen in the mergers, but always fewer in number, and generally fainter in luminosity. It appears that wherever you have regions of star formation, you have young massive clusters being formed, not just in mergers ! Essentially all the cluster luminosity functions in merging and starbursting galaxies are power laws with index ~ -2. Whitmore, 2000 Power law luminosity functions with index -2 appear to be the norm, in spiral galaxies as well as merging and starburst galaxies. Larsen (2002) Mergers and starburst galaxies may have the brightest clusters only because they have the most clusters (i.e., there may be a “universal” luminosity function with the correlation simply being due to statistics, not special physics). Whitmore, 2000 mergers Best fit (i.e., a size-of-sample effect) spirals Larsen (2002) has shown that a similar relation holds versus the total star formation in a galaxy. Predicted if universal power-law, index = -2 Fall, Chandar & Whitmore (2005) show that 90 % of the young clusters in the Antennae are disrupted each decade of time (i.e, infant mortality). The disruption rate appears to be independent of mass to first order. Fall, Chandar & Whitmore 2005 The disruption rate appears to be a power law with index –1 for the Antennae, the SMC (Rafelski & Zaritsky 2005), and the MW (Lada & Lada 2003). Universal destruction rate ? The Big Picture - A General Framework for Understanding the Demographics of Star Clusters Ingredients (assume all stars form in clusters) : 1. A universal initial mass function (power law, index -2) 2. Various star(cluster) formation histories 3. Various cluster disruption mechanisms (e.g., T**-1 < 100 Myr, 2-body relaxation > 100 Myr) 4. Convolution with observational artifacts and selection effects Observations (luminosity and age distributions, color-color diagrams, total luminosity of a galaxy, fraction of field stars, …) Here is an example of two of our models based on observations of the Antennae. Whitmore, Chandar, Fall (2006) Whitmore, Chandar, & Fall Probably the most relevant output from the model for the present discussion is the prediction of the fraction of stars in the field, as discussed earlier. (2006) model Our Antennae model predicts ~ 8 % of the UV luminosity is from clusters, in agreement with observations ( ~10 %). Hence, our data is consistent with the idea that all stars are born in clusters. ~ median age of observed clusters Summary 1. The small-scale velocity dispersion between clusters is remarkably quiescent (e.g, ~ 10 km/sec), indicating that high-velocity cloud-cloud collisions are not the triggering mechanism for cluster formation. 2. Observations in both the Milky Way and external galaxies support the idea that essentially all stars are formed in groups and clusters. 3. The most luminous (massive) stars in external galaxies as far away as the Antennae (~ 20 Mpc) can be differentiated from the clusters. 2. A general framework has been developed to explain the demographics of stars and star clusters in galaxies. Important aspects are; • Assumption that all stars are born in groups and clusters. • An initial mass distribution which is a power law with index = -2 • Infant mortality of ~90 % of the clusters each decade of time.