Feeding Galaxy Caught in Distant Searchlight
Astronomers have always suspected that galaxies grow by pulling in material from their
surroundings, but this process has proved very difficult to observe directly. Now ESO’s Very Large
Telescope has been used to study a very rare alignment between a distant galaxy
[1]
and an even more distant quasar — the extremely bright centre of a galaxy powered by a
supermassive black hole. The light from the quasar passes through the material around the
foreground galaxy before reaching Earth, making it possible to explore in detail the properties of
the gas around the galaxy
[2]. These new results give the best view
so far of a galaxy in the act of feeding.
“
This kind of alignment is very rare and it has allowed us to make unique observations,”
explains Nicolas Bouché of the Research Institute in Astrophysics and Planetology (IRAP) in
Toulouse, France, lead author of the new paper. “
We were able to use ESO’s Very Large Telescope to peer at both the galaxy itself and its
surrounding gas. This meant we could attack an important problem in galaxy formation: how do
galaxies grow and feed star formation?”
Galaxies quickly deplete their reservoirs of gas as they create new stars, and so must somehow
be continuously replenished with fresh gas to keep going. Astronomers suspected that the answer to
this problem lay in the collection of cool gas from the surroundings by the gravitational pull of
the galaxy. In this scenario, a galaxy drags gas inwards, which then circles around the galaxy,
rotating with it before falling in. Although some evidence of such accretion had been observed in
galaxies before, the motion of the gas and its other properties had not been fully explored up to
now.
The astronomers used two instruments known as
SINFONI
and
UVES
[3], both of which are mounted on ESO’s VLT
at the Paranal Observatory in northern Chile. The new observations showed both how the galaxy
itself was rotating, and revealed the composition and motion of the gas outside the galaxy.
“
The properties of this vast volume of surrounding gas were exactly what we would expect to find
if the cold gas was being pulled in by the galaxy,” says co-author Michael Murphy (Swinburne
University of Technology, Melbourne, Australia). “
The gas is moving as expected, there is about the expected amount and it also has the right
composition to fit the models perfectly. It’s like feeding time for lions at the zoo — this
particular galaxy has a voracious appetite, and we’ve discovered how it feeds itself to grow so
quickly.”
Astronomers have already found evidence of material around galaxies in the early Universe, but
this is the first time that they have been able to show clearly that the material is moving inwards
rather than outwards, and also to determine the composition of this fresh fuel for future
generations of stars. Without the quasar’s light to act as a probe this surrounding gas would be
undetectable.
“
In this case we were lucky that the quasar happened to be in just the right place for its light
to pass through the infalling gas. The next generation of extremely large telescopes will enable
studies with multiple sightlines per galaxy and provide a much more complete view,” concludes
co-author Crystal Martin (University of California Santa Barbara, USA).
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[1] This galaxy was detected in the 2012 redshift z ~ 2 SINFONI survey
called the SINFONI Mg II Program for Line Emitters (
SIMPLE
). The quasar in the background is called QSO J2246-6015, or HE 2243-60 and the galaxy itself
lies at a redshift of 2.3285 — meaning that we are seeing it when the Universe was just about two
billion years old.
[2] When the quasar light passes through the gas clouds some wavelengths are
absorbed. The patterns of these absorption fingerprints can tell astronomers much about the motions
and chemical composition of the gas. Without the quasar in the background far less information
would have been be obtained — the gas clouds do not shine and are not visible in direct
images.
[3] SINFONI is the Spectrograph for INtegral Field Observations in the Near
Infrared, while UVES is the Ultraviolet and Visual Echelle Spectrograph. Both are mounted on ESO’s
Very Large Telescope. SINFONI revealed the motions of the gas in the galaxy itself and UVES the
effects of the gas around the galaxy on the light coming from the more distant quasar.