[ ♪ Intro ]
Galaxies are all over the news this week!
Galaxies near, galaxies far, galaxies wherever
you are … and, yes, that does mean the Milky Way.
But first, in a paper published this week
in the journal Nature, an international team
of astronomers discovered that a distant galaxy
has almost no dark matter, throwing our expectations
straight out the window.
Dark matter isn’t so much dark as it is
invisible to all current methods of detection.
It doesn’t interact with light at all, so
we can’t see it, but it does have mass,
so we can see the effects of its gravitational
pull.
In most galaxies, dark matter is more abundant
than regular, or baryonic, matter.
In our own Milky Way it outnumbers baryonic
matter roughly 30 to 1, but in dwarf galaxies,
that ratio is over 10 times greater!
So to find a small galaxy with almost no dark
matter at all would be super weird.
So, obviously, we found one.
It’s called NGC1052–DF2, although we’ll
just call it DF2 for short.
To figure out how much dark matter it has,
astronomers needed to compare the mass of
the matter we can see to the galaxy’s total
mass.
They were able to determine DF2’s stellar
mass, or how much of its mass comes from stars,
based on its brightness and distance.
The team estimated that it’s around 65 million
light-years away, which produced a stellar
mass of about 200 million times the mass of
the Sun, which is roughly 250 times less than
that of the Milky Way.
Then they calculated the mass of the halo
surrounding the galaxy, which should, theoretically,
be chock full of dark matter.
To do that, they measured the velocities of
10 different star clusters at distances between
1300 and 25,000 light-years from the center.
Since a more massive galaxy will make stars
orbit faster, they used those clusters’
velocities to calculate the total mass for
the whole galaxy.
Then they subtracted the stellar mass they’d
already accounted for, which left them with
the mass of the dark matter halo.
Which turned out to be less than 150 million
times the mass of the Sun.
Now, that’s not zero dark matter, but current
models say the number should be closer to
60 billion solar masses — 400 times more
than what we’re seeing!
Since it’s such a unique oddity, we still
don’t know how a dark matter deficient galaxy
like DF2 came to be.
The team proposed a few ways it might have
formed from regular matter that wouldn’t
have taken much dark matter with it.
For example, from gas that was flung out of
merging galaxies, or that was streaming toward
a neighboring galaxy but ended up splitting
off.
Until we find more galaxies like this one,
it’ll be tough to come up with a solid origin story.
But the discovery does help show that dark
matter and baryonic matter are not inexorably
linked to one another — in other words,
the amount of one does not determine the amount
of the other.
And, it helps put another nail in the coffin
for hypotheses that dark matter isn’t real,
and that what we call dark matter is actually
just our own physics equations being wrong.
Because if that were the case, we wouldn’t
expect to find random galaxies with very little of it.
As for when we’ll finally pin down what
exactly dark matter is, only time will tell.
Much closer to home, astronomers have finally
solved a mystery involving a galactic tug
of war and cannibalism on the outskirts of
the Milky Way.
The Large and Small Magellanic Clouds are
irregular dwarf galaxies about 160,000 and
200,000 light-years from our own.
They both orbit the Milky Way, but as they
do so, they also orbit one another.
The gravity involved in that system means
that one of the Clouds has ripped away some
of the other’s gas, and sent it spiraling
toward us in a fragmented arc roughly half
the length of the Milky Way!
The question is: which Cloud is siphoning
gas away from the other?
That’s been a mystery for some time now
— although admittedly not as long as the
arc has been around, since it’s roughly
2 billion years old.
Obviously we weren’t around back then to
ask these kinds of questions.
Thanks to a paper published last month in
the Astrophysical Journal, we may finally
have an answer.
Astronomers call this arc of gas the Leading
Arm, because it’s “leading the motion”
of the Magellanic Clouds.
It kinda looks like this arm starts out in
the Large Magellanic Cloud.
But to confirm its real galactic parent, the
team used the Hubble Space Telescope to analyze
some of its composition, and compare it to
both dwarf galaxies.
Specifically, they looked at the light from
seven quasars, incredibly bright cores of
galaxies powered by supermassive black holes.
Based on where they’re each located in space,
the light from these quasars had to travel
through one of the Magellanic Clouds or the
Leading Arm on its way to us.
And depending on their composition, the molecules
in the Clouds and Arm would have absorbed
different wavelengths of the light as it passed
through.
By analyzing which types of light were absorbed,
the team was able to match the Arm’s composition
with … the Small Magellanic Cloud.
Large Magellanic Cloud, you are not the father!
Or mother.
But you did kind of gravitationally tear off
part of your galactic partner and allow the
Milky Way to cannibalize it and make new stars,
so it’s complicated.
Of course solving this mystery wasn’t just
to satisfy curiosity.
Understanding how gas falls - or accretes
- into galaxies is an important step toward
better models of how galaxies grow and evolve.
But most galaxies are too far away for us
to detect the light we’d need to study.
So the fact that we have an example of this
galactic gas accretion right on our own front
porch is a huge benefit.
Between that and DF2’s missing dark matter,
we’ve got all kinds of galactic mysteries to solve!
Thanks for watching this episode of SciShow
Space News!
For more on galaxies with weird amounts of
dark matter, you can check out our episode
on Galaxy X, which is almost entirely made
up of dark matter.
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