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| NASA Spitzer Space Telescope's infrared image of the Andromeda galaxy. Credit: NASA/JPL-Caltech/Univ. of Ariz. |
There's a growing body of evidence that galaxies grow large by merging with
other galaxies.
Telescopes like the Hubble have captured dozens of interacting galaxies,
including well-known ones like Arp 248.
The Andromeda galaxy is the nearest large galaxy to the Milky Way, and a new
study shows that our neighbor has consumed other galaxies in two distinct
epochs.
"A few years ago, we discovered that in the far outskirts of Andromeda,
there was a sign in the objects orbiting it that the galaxy hadn't been
grazing, but it had eaten large quantities in two distinct epochs,"
said Geraint Lewis
from the University of Sydney.
Lewis is the lead author of a new paper titled "Chemo-dynamical substructure in the M31 inner halo globular clusters:
Further evidence for a recent accretion event." The Monthly Notices of the Royal Astronomical Society will publish the
paper, and it's currently available at the pre-press site arxiv.org.
"What this new result does is provide a clearer picture of how our local
universe has come together – it is telling us that at least in one of the
large galaxies, there has been this sporadic feeding of small galaxies,"
Lewis said in a
press release.
Globular clusters are at the center of this research.
They're older associations of stars that have lower metallicity. There are
at least 150 in the Milky Way, likely more. They play a role in galactic
evolution, but the role isn't clearly understood. Globulars, as they're
known, are more prevalent in a galaxy's halo, while their counterparts, open
clusters, are found in the galactic disks.
The researchers behind this work identified a population of globulars in
Andromeda's inner halo that all have the same metallicity. Metallicity
refers to the elemental makeup of stars, with elements heavier than hydrogen
and helium referred to as metals in astronomy.
The globulars have lower metallicity than most stars in the same region,
meaning they came from elsewhere, not from Andromeda itself.
It also means they're older since there were fewer heavy elements in the
early Universe than there are now.
Lewis named the collection of globulars the Dulai Structure, which means
black stream in Welsh.
The Dulais Structure is likely a group of between 10 and 20 globulars
misaligned with Andromeda's rotation. But they're not the only misaligned
group of globulars.
The Dulais Structure is evidence of Andromeda feeding on a group of
globulars sometime in the last 5 billion years. The other group is a
sub-population of globulars that's evidence of a second feeding event
between 8 to 10 billion years ago.
According to Lewis and his co-authors, the globular clusters have lower
metallicity and are also kinematically distinct from other clusters in the
same region. The Andromeda galaxy rotates one way, and the Dulais Structure
moves differently.
To Lewis and his co-authors, the Dulais Structure looks like the leftovers
from a messy meal. It's a dark stream containing vibrant star clusters. It's
further evidence that massive galaxies merge to produce gigantic displays
throughout the Universe and that larger galaxies consume smaller globulars
in a type of galactic cannibalism.
"That then leads to the next question of, well, what was actually consumed?
Because it doesn't look like it was just one thing, it looks like it's been
a collection of things that are all slowly torn apart," said Lewis.
"We've come to realize over the last few decades that galaxies grow by
eating smaller systems – so little galaxies fall in, they get eaten – it's
galactic cannibalism."
When these feeding events occurred, matter in the Universe was more tightly
concentrated. Ten billion years ago, there may have been more of these
events throughout the Universe. That's one of the reasons astronomers desire
more and more powerful telescopes like the James Webb. They can see the
light from ancient galaxies and look further back in time.
"We know that the Universe was featureless at its birth in the Big Bang, and
today it's full of galaxies. Were those galaxies born fully formed, or have
they grown?" Lewis said.
Astronomers would like to know the history of our own Milky Way galaxy. We
all would. That's difficult to do through observations because we're
embedded in it.
But Andromeda presents an opportunity to study galaxy evolution from an
external perspective, and researchers like Lewis and his colleagues are
taking full advantage.
As a spiral galaxy similar to the Milky Way, some of what astronomers learn
about galaxy mergers from Andromeda can apply to our galaxy, too.
But astronomers have more work to do before they can draw conclusions about
the Milky Way. Or about mergers and consumptions in general. A more detailed
timeline of galactic evolution throughout the Universe is the goal.
"What we want to know is, has the Milky Way done the same, or is it
different? Both of those have interesting consequences for the overall
picture of how galaxies form," Lewis said.
"We want to, at some level, come up with a more accurate clock to tell us
when these events occurred because that's one thing we need to include in
our models of how galaxies evolve."
As it stands, Lewis and the other researchers only have a two-dimensional
historical view of the Dulais Structure.
The dimensions are speed and chemistry. Finding the distances of all these
objects will provide a third dimension, which will fill out the history of
the globulars and how Andromeda consumed them.
Lewis isn't absolutely certain we can call them globulars at this point, and
he won't be until there's more data. Hence the name "Dulais Structure."
"That will then allow us to work out orbits, where things are going, and
then we can start to run the clock backwards and see if we can get this
coherent picture of when things fell in," he said.
"We couldn't name it as an object like a galaxy because we actually do not
know if the signature we see is from one big object disrupting or seven
smaller objects disrupting. That's why we sort of refer to it as a structure
rather than it being a particular galaxy."
There's obviously something going on with the Dulais Structure and the
Andromeda galaxy. But true to his scientific training, Lewis is cautious
about firm conclusions at this stage.
"It's opened a new door in terms of our understanding," Lewis said in a
press release. "But exactly what it's telling us, I think we still have to
work that one out."
The authors state their case clearly in their paper. "Intriguingly, the
orbital axis of this Dulais Structure is closely aligned with that of the
younger accretion event recently identified using a sub-population of
globular clusters in the outer halo of Andromeda, and this is strongly
suggestive of a causal relationship between the two," the authors
summarize in their paper.
"If this connection is confirmed, a natural explanation for the kinematics
of the globular clusters in the Dulais Structure is that they trace the
accretion of a substantial progenitor (about 1011 solar masses) into the
halo of Andromeda during the last few billion years, which may have occurred
as part of a larger group infall."
This article was originally published by Universe Today. Read the
original article.
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Space & Astrophysics