Galaxies are constantly forming new stars within dense clouds of interstellar
material. The star formation rate in today's galaxies is, however, much lower
than it used to be. When the universe was about a quarter its current age, star
formation was at its peak, and so astronomers are keen to learn about this
period. Looking back in time is possible because of the finite speed of light,
but only by looking out to great distances, which in turn means that young
galaxies appear very small and very faint. In addition, most of their new-born
stars cannot be seen directly, because their radiation is absorbed by dust in
the surrounding gas cloud and is re-emitted at far-infrared wavelengths.
As a result, star-forming regions in distant galaxies are one of the prime
targets for the Atacama Large Millimetre/submillimetre Array. ALMA will consist of
66 high precision antennas, located on the Chajnantor plateau at 5000 meters
altitude in northern Chile. The data from the individual antennas can be
combined interferometrically, and the 15 kilometre span of the telescope
provides resolution of better than a tenth of an arc-second. On its own,
however, even this capability is not sufficient to make detailed pictures of
young galaxies at the peak of their star formation.
"At a recent conference, ALMA scientists presented data they had used to verify
the scientific capabilities of their array, among them an image of a strongly
gravitationally lensed system, which immediately raised our interest", remembers
Simona Vegetti, postdoctoral scientist at MPA. "Because of the lensing, the
background galaxy is strongly magnified, by 17 times actually, which is why we
can see it at all. Together with ALMA's unique angular resolution, this gave us
the chance to try and see details in the distribution of dust in such a far-away
galaxy for the first time."
Strong gravitational lensing happens when a background galaxy is closely aligned
with a foreground mass concentration such as a cluster of galaxies, which bends
light-rays from the source on their way to the observer. The foreground lens is,
however, an imperfect optical system, leading to very large distortions (see
Fig. 1). Nevertheless, from the properties of the lensed images, the mass
distribution of the lensing system can be determined and a "true" (i.e.
undistorted) image of the distant galaxy can be reconstructed.
"Previous attempts to do this had assumed the background galaxies to be smooth
and regular", explains Matus Rybak, who carried out the computer modelling at
MPA. "This seems likely to be a very poor approximation to the structure of a
strongly star-forming galaxy, and the raw ALMA images gave clear hints that this
background source is complex. The new, more general approach we have developed
is much better suited to irregular systems."
This intuition is borne out by the reconstructed image of the galaxy SDP.81
which shows star formation to be concentrated in three distinct regions (see
Fig. 2). "This is the first time, that we can see structure in the dust emission
of a z=3 galaxy on scales smaller than 150 light-years", points out Simona
Vegetti. At this cosmic time, typical galaxies were forming stars at their peak
rate, and indeed SDP.81 is forming about 300 solar masses of stars every year.
(In our Milky Way, the star formation rate is about 3 solar masses per year.)
The complex structure of the galaxy may indicate that it is a rotating disk with
a central bulge that is seen (and lensed) edge-on; alternatively it may be a
system which is undergoing a merger in which the separate components are still
visible. To distinguish between these possibilities, data on the motions of gas
within the galaxy are needed, so the next step for the MPA team together with
their colleagues Paola Andreani at ESO and John McKean at the University of Groningen and the Netherlands Institute for Radio Astronomy (ASTRON) will be to analyse the
molecular line observations of this system which ALMA has also obtained.
ALMA imaging of SDP.81 I. A pixelated reconstruction of the far-infrared
continuum emission, M. Rybak, J. P. McKean, S. Vegetti, P. Andreani and S. D. M.
White, submitted to MNRAS
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