This work also involves researchers from the Research Institute for Astrophysics and Planetology in Toulouse and Astrophysics Research Center of Lyon in France; Geneva University and Ecole Polytechnique Federal de Lausanne in Switzerland; and the University of Arizona in the United States.
Thanks to the high data quality of Hubble in the optical and near-infrared and Spitzer in infrared data, these astrophysicists have determined the properties of this young galaxy with a better precision than previous studies of other samples at similar cosmic epochs. This galaxy, named Abell2744_Y1, is about 30 times smaller than the Milky Way but is producing at least 10 times more stars. From Earth, this object is seen as it was 650 million years after the Big Bang. Its light has traveled about 13 billion years to reach the telescopes, being one of the brightest galaxies discovered at such distances. In astronomy, the farther one object is, the longer it takes for the light to reach us, and therefore the Frontier Fields allow the astronomers to push the limits of the observable universe. This study provides new constraints on the density and properties of the galaxies in the early universe.
Last month, during the meeting of the American Astronomical Society held in Washington, D.C., the Space Telescope Science Institute presented its flagship project for the next three years: the “Hubble Frontier Fields.” In the framework of this program, three of the most powerful space telescopes to date — Hubble, Spitzer, and Chandra — will dedicate a large amount of their observing time to investigate six galaxies clusters, which act as additional lenses and amplify the light from background sources, including faint galaxies to the edge of the observable universe. This will allow astronomers to study for the first time fainter and smaller galaxies in the first billion years of the universe.
The first long-exposure image of cluster Abell 2744, obtained in the last months, is the deepest one obtained so far of a cluster of galaxies and is comparable to the previous Hubble Ultra Deep Field, which is a blank region of the sky. All the Frontier Fields clusters have been carefully selected and are the best ones for this kind of study.
Thanks to the gravitational lensing by the cluster, the light of the background galaxies can be magnified by a large amount. This effect converts in practice the Hubble Space Telescope into an equivalent telescope with a collecting area several hundred times larger.
“We expected to find very distant galaxies close to the cluster core, where the light amplification is maximum,” said Nicholas Laporte from the IAC. “However, this galaxy is very close to the edge of the Hubble image where the light is not strongly amplified. We are really lucky that we could find it in the small field of view of Hubble. In a related study led by Hakim Atek from EPFL in Lausanne, more galaxies are analyzed but none is more distant than Abell2744_Y1.”
The analysis of the observations of this cluster carried out with the Spitzer Space Telescope has been crucial to estimate the properties of Abell2744_Y1. Alina Streblyanska from the IAC commented that the Spitzer observations combined with the Hubble ones provide a good estimate of the distance to this galaxy: “They also suggest that Abell2744_Y1 contains not only stars but also a large amount of gas.”
Ismael Pérez-Fournon from the La Laguna University pointed out that last year his group contributed to the discovery of an exceptional star factory in the early universe, called HFLS3, with the Herschel Space Observatory: “HFLS3 has extreme properties in the far-infrared, observed 880 million years after the Big Bang. Abell2744_Y1 is a smaller galaxy, less massive but more distant and much more representative of the early universe. Both types of galaxies are equally important to understand how galaxies formed and evolved.”
In coordination with the Hubble observations, the Spitzer Space Telescope and Chandra X-ray Observatory are taking very deep exposures of the Frontier Fields. Since the end of 2013, the data of the first cluster obtained by the first two telescopes are available to the whole scientific community.
Observations of the Frontier Fields by Hubble, Spitzer, and Chandra are in an early stage but have already shown the exceptional potential of this new project to study the first luminous objects in the universe. As it happnened with other Hubble initiatives on deep fields, many other observatories all over the world and in space will join the effort with additional observations of the Frontier Fields. An unprecedented scientific legacy for future studies with the present large telescopes as the Gran Telescopio Canarias, and the future extremely large telescopes as the E-ELT and the James Webb Space Telescope is expected.