Paris, 9 February 2012
Mergers of massive, gas-rich galaxies are veritable fireworks of star formation, and many of the stars in galaxies formed during such short, vigorous events, from the early history of the Universe until today.
Such outbursts of star formation, starbursts, trigger the formation of giant clusters of millions of young stars within a few tens of light years. Similar volumes around our own solar system only contain a handful of stars.
Astronomers discovered the first super star clusters in the Antennae galaxy merger in images taken with the Hubble Space Telescope nearly 20 years ago, but until now, the physical processes which led to their formation were largely unknown. By combining the first ALMA data of the Antennae with observations previously obtained at the ESO VLT, the scientists are now able to trace directly how the galaxy merger triggers the formation of super star clusters. This study forms the backbone of Ms. Herrera's thesis work at the IAS in Orsay. A Chilean graduate student, she is doing her PhD thesis in France as part of a bilateral program between the CNRS and CONICYT (Chile). Understanding the astrophysical processes that lead to star formation and galaxy growth is one of the overriding scientific goals of ALMA.
Rather than studying young star clusters after they form, as has been done previously, Ms. Herrera followed a new approach by quantifying the energy lost by the gas in the star-forming clouds of the Antennae. Stars form from gas that is dense and very cold, however, in the Antennae, the galaxy merger stirs up the gas, making it highly turblent. To form new stars, the gas must lose this turbulent energy, so that it can cool, condense, and eventually collapse into a new star cluster.
This immense energy loss, predicted by theory, is now visible by using ALMA and the VLT. As the gas settles into gas clouds, and cools down, it emits a faint glow of light which can be observed with the VLT in the near-infrared. However, seeing this glow alone was not enough. The scientists also had to measure the turbulence in the surrounding gas clouds created by the galaxy merger, which is now possible with ALMA.
In only one of these clouds, the researchers found a clump of gas, massive enough to form a new super star cluster itself, which is radiating its turbulent energy very rapidly. In this region, where the gravitational pull of the galaxy merger is as its strongest, ALMA only sees an ordinary cloud, which for the VLT is the brightest object in all of the Antennae galaxies. In only a few million years, the blink of an eye in a galaxy's lifetime, this cloud will have lost all its turbulence, and a new cluster will be born. This first example illustrates the plethora of exciting new discoveries that astronomers like Ms. Herrera are hoping to make once ALMA reaches its full capabilities.
Photomontage illustrating the discovery of a super star cluster in the Antennae galaxies.
Bottom left: landscape image showing the two galaxies interacting, just as they were discovered in the last century
Top left: close-up on the central region, where both galaxies interpenetrate. Image obtained by NASA's Hubble telescope.
The images on the right-hand side, prepared by Cinthya Herrera, illlustrate the observations carried out by ALMA and VLT. The ALMA image, to the left, shows the clouds containing the youngest and largest star clusters (star symbol). The VLT image, on the right, shows the energy radiation from clouds. The bright compact source in this image (red) is present where two masses of gas moving at very different speeds (in red and blue inside the frame in the bottom right) collide.
Observations show that this is where energy loss is at its highest and that conditions are met to form a new cluster within a few million years.
ALMA CO and VLT/SINFONI H2 observations of the Antennae overlap region: mass and energy dissipation. Herrera, C. N., Boulanger F., Nesvadba, N. P. H., Falgarone, E. 2012, A&A, volume 538, L9
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