Herschel’s infrared view of part of the Taurus Molecular Cloud, within
which the bright, cold pre-stellar cloud L1544 can be seen at the lower
left. It is surrounded by many other clouds of gas and dust of varying
density.
The Taurus Molecular Cloud is about 450 light-years from Earth and is
the nearest large region of star formation.
The image covers a field of view of approximately 1 x 2 arcminutes.
Credits: ESA/Herschel/SPIRE
Large water reservoirs at the dawn of stellar birth
ESA’s
Herschel space observatory has discovered enough water vapour to fill
Earth’s oceans more than 2000 times over, in a gas and dust cloud that
is on the verge of collapsing into a new Sun-like star.
Stars form within cold, dark clouds of gas and dust – ‘pre-stellar cores’ – that contain all the ingredients to make solar systems like our own.
Stars form within cold, dark clouds of gas and dust – ‘pre-stellar cores’ – that contain all the ingredients to make solar systems like our own.
Water, essential to life on Earth, has previously been detected outside
of our Solar System as gas and ice coated onto tiny dust grains near
sites of active star formation, and in proto-planetary discs capable of
forming alien planetary systems.
The new Herschel observations of a cold pre-stellar core in the
constellation of Taurus known as Lynds 1544 are the first detection of
water vapour in a molecular cloud on the verge of star formation.
More than 2000 Earth oceans-worth of water vapour were detected,
liberated from icy dust grains by high-energy cosmic rays passing
through the cloud.
“To produce that amount of vapour, there must be a lot of water ice in
the cloud, more than three million frozen Earth oceans’ worth,” says
Paola Caselli from the University of Leeds, UK, lead author of the paper
reporting the results in Astrophysical Journal Letters.
“Before our observations, the understanding was that all the water was
frozen onto dust grains because it was too cold to be in the gas phase
and so we could not measure it.
Close-up of L1544
with the water spectrum seen by Herschel, taken from the centre of the
pre-stellar core. The peak of the graph shows an excess in brightness,
or emission, while the trough shows a deficit, or absorption. These
characteristics are used to indicate the density and motions of the
water molecules within the cloud. Emission arises from molecules that
are approaching the centre where the new star will form, from the back
of the cloud from Herschel’s viewpoint. The amount of emission indicates
that these molecules are moving within the densest part of the core,
which spans about 1000 Astronomical Units. The absorption signature is
due to water molecules in front of the cloud flowing away from the
observer towards the centre. These water molecules are in less dense
regions much further away from the centre. Together, the emission and
absorption signatures indicate that the cloud is undergoing
gravitational contraction, that is, it is collapsing to form a new star.
Herschel detected enough water vapour in L1544 to fill Earth’s oceans
more than 2000 times over.
Credits: ESA/Herschel/SPIRE/HIFI/Caselli et al.
Now we will need to review our understanding of the chemical
processes in this dense region and, in particular, the importance of
cosmic rays to maintain some amount of water vapour.”
The observations also revealed that the water molecules are flowing
towards the heart of the cloud where a new star will probably form,
indicating that gravitational collapse has just started.
“There is absolutely no sign of stars in this dark cloud today, but by
looking at the water molecules, we can see evidence of motion inside the
region that can be understood as collapse of the whole cloud towards
the centre,” says Dr Caselli.
“There is enough material to form a star at least as massive as our Sun,
which means it could also be forming a planetary system, possibly one
like ours.”
Some of the water vapour detected in L1544 will go into forming the
star, but the rest will be incorporated into the surrounding disc,
providing a rich water reservoir to feed potential new planets.
“Thanks to Herschel, we can now follow the ‘water trail’ from a
molecular cloud in the interstellar medium, through the star formation
process, to a planet like Earth where water is a crucial ingredient for
life,” says ESA’s Herschel project scientist, Göran Pilbratt.
Notes for Editors
European Space Agency (ESA)
Guillermo Gonzalo Sánchez Achutegui
ayabaca@gmail.com
ayabaca@hotmail.com
ayabaca@yahoo.com
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