CALIFA: The local extragalactic universe unveiled
Together with the data release, two technical publications authored by members of the CALIFA collaboration have been made publicly available, describing the data and showing some of their scientific applications.
"I am tremendously happy to see a dream come true" says Sebastián Sánchez, Principal Investigator of CALIFA. "When we first thought of CALIFA, five years ago, the perspective of releasing such wonderful data seemed far off, yet it is happening right now! We hope and expect that the scientific community will make use of the opportunity."
Galaxies are the end products of cosmic evolution along cosmological times, and their secret history is hidden in the properties of their different components. CALIFA is an on going project running at Calar Alto Observatory, focused on characterizing the galaxies in the local universe with unprecedented detail, trying to uncover these archaeological treasures.
To this end, CALIFA uses the technique called integral field spectroscopy (IFS) to obtain data of 600 galaxies in the local universe. Traditional observational studies in extragalactic astronomy used one of two classical techniques: either imaging, which gives detailed information about the spatial extent of galaxies, or spectroscopy, which gives detailed information about many properties of galaxies, but no or very little information on the spatial distribution of them. The recent technology of IFS allows taking a multitude of simultaneous spectra at many points on each galaxy, thanks to a clever combination of fibre optics and classical techniques. CALIFA is the first IFS study to be explicitly designed as a legacy project and, upon completion, it will be the largest survey of this kind ever accomplished.
The integral field spectrograph used for the CALIFA survey at Calar Alto Observatory, PMAS (in a special configuration called PPAK) was built at AIP. It uses more than 350 optical fibres to cover a field of view of one square arcminute (equivalent to the apparent width of a 1 euro coin placed at a distance of approximately 80 metres). This way, a complete extended object, such as a galaxy, can be fully mapped in detail in just one exposure.
The delivered data allow producing maps for the different properties of galaxies, such as velocity, stellar ages or chemical composition, to mention just a few. This information will yield new insights in several key issues linked to the structure and history of galaxies in the universe. It is expected to reach results, for instance, on which processes drove galaxy evolution in time, how the chemical elements needed for life are produced inside different galaxies or at different regions inside individual galaxies, the phenomena involved in galaxy collisions. This wealth of information allows to uncover the history not only of an entire galaxy, but also of its different components.
"The amount of science we can do is simply incredible" says Jakob Walcher, from the Leibniz Institute for Astrophysics Potsdam (AIP) and Project Scientist of CALIFA. "We can study local processes that drive galaxy evolution and that happen at different places in the galaxies, such as star formation, dynamical effects etc. But we also globally characterize the properties of galaxies in the local universe in a way that was not possible before. For example we map the 2D distribution of the stellar mass and chemical elements in the galaxies. Finally, our large sample will allow us to draw comparisons between different galaxy types."
Calar Alto Observatory is jointly operated by the Max Planck Institute for Astronomy (MPIA-MPG, Heidelberg, Germany) and the Astrophysical Institute of Andalusia (IAA-CSIC, Granada, Spain). The Observatory has guaranteed 250 observing nights (distributed along three years) for the CALIFA Survey with the 3.5 m Zeiss reflector, supporting the acquisition, reduction and data storage processes. To accomplish this enormous effort the concourse of a large collaboration of astronomers is required, its composition reflecting the dual Spanish/German heritage of the Observatory. However, it also includes participants from all over the world, comprising a total of 80 people from 13 nations spread among 25 research institutes, from so far away as Australia and Canada or the USA.
AIP in particular is strongly involved in CALIFA. The instrument (PMAS) was built in Potsdam. AIP also contributed strongly to the data reduction pipeline and the project lead. Scientists at AIP will exploit the data to study the kinematics of galaxies, the abundances of the chemical elements in galaxies and the importance of AGN.
Science contact: Dr Jakob Walcher, email@example.com
Media contact: Kerstin Mork, +49 331-7499-469, firstname.lastname@example.org
The key areas of research at the Leibniz Institute for Astrophysics (AIP) are cosmic magnetic fields and extragalactic astrophysics. A considerable part of the Institute's efforts aim at the development of research technology in the fields of spectroscopy, robotic telescopes, and e-science. The AIP is the successor of the Berlin Observatory founded in 1700 and of the Astrophysical Observatory of Potsdam founded in 1874. The latter was the world's first observatory to emphasize explicitly the research area of astrophysics. The AIP has been a member of the Leibniz Association since 1992.