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Giants of the Universe Probe Cosmic Questions
NASA: We have booster ignition and liftoff of Columbia, reaching new heights for women
and X-ray Astronomy.
Martin Elvis: The main thing Chandra does is take these superb, sharp images.
Cady Coleman: Nothing as beautiful as Chandra trailing off on its way to work
Narrator: Did you know that galaxies don't like to be alone? It's not that galaxies feel
a social need to congregate with others. Rather, it's their gravitational pull -- even across
the vast distances of space -- that can cause galaxies to form clusters that can contain
hundreds or even thousands of individual galaxies.
Clusters of galaxies are, in fact, the largest structures in the Universe that are held together
by gravity. Because of their immense size and mass, galaxy clusters are extremely useful
as tools to probe a variety of questions about the Universe as a whole as well as properties
of the clusters themselves.
Dr. Christine Jones of the Chandra X-ray Center discusses the importance of galaxy clusters
and the wide-range of astrophysical topics they can address.
Christine Jones: Since clusters are so large and so massive, they're a great place to take
an inventory of the mass in the Universe, in particular how much is luminous matter
and how much is dark matter. We also can study the individual galaxies in clusters and learn
what kind of galaxies live in different environments and how the galaxies which are often moving
in the cluster at speeds of 1000 km/second interact both with each other and with the
cluster gas. In addition to being massive, clusters are so luminous that they can be
observed back to when the Universe was only half its present age. Comparing the properties
of distant clusters with nearby ones allows us to see both how clusters grow over time
as smaller clusters fall into them, and also lets us constrain important cosmological parameters.
Narrator: While galaxy clusters are indeed comprised of individual galaxies, that is
not their entire story. That's because these clusters are filled with colossal clouds of
hot gas. These clouds have temperatures as high as 100 million degrees and much more
mass than all of the stars in the galaxies in the cluster. Because this gas is so hot,
the only way to observe it is through X-ray telescopes like the Chandra X-ray Observatory.
Christine Jones: One of the incredible insights we've seen with Chandra is the impact that
outbursts from a supermassive black hole at the center of the central galaxy in some clusters
has had on the gas in the cluster. In several dozen clusters we've now seen X-ray cavities,
some with sizes larger than the entire Milky Way, where expanding radio lobes from the
black hole have pushed the hot gas out of these regions. The energy in these outbursts
is enormous, more than billions of supernovae. In a few clusters, we've also seen shocks
in the gas that are produced by these outbursts. With these Chandra observations, we can measure
how much energy has come out since the outburst began, how long the outburst lasted and how
often these outbursts occur.
Narrator: One of the most important questions galaxy clusters can help astronomers address
is concerning dark matter. Dark matter is an unknown substance that comprises 90% of
all of the matter in the Universe. Using Chandra and optical telescopes, scientists have been
able to find direct proof of the existence of dark matter for the first time.
Christine Jones: In clusters, as in the Universe, most of the mass appears to be in the form
of dark matter. While we can't directly see where the dark matter is, we can determine
how much there is and where it is. One of the best examples of a merging cluster is
one we call the bullet cluster. Most of the gas in this subcluster has been stripped off
and pushed back from the subcluster galaxies. So the question is, where is the dark matter?
Some alternative theories of gravity have suggested that gravity behaves differently
on a large scale and that in clusters, the hot gas alone might be enough to provide the
gravity. What we found for the bullet cluster was that observations of distant galaxies
behind the cluster showed that their light was distorted into arcs by the dark matter
in the cluster. These observations showed that the dark matter was concentrated into
two regions, one on the large primary cluster and a second at the front of the bullet. Since
the X-ray gas is no longer at the front of the bullet where the dark matter is, the gas
can't be making up the dark matter. So while we still don't know what does make up the
dark matter, we know it's not the gas and must be something different that interacts
much less than the gas does.
Narrator: Galaxy clusters are proving to be some of the most fascinating structures in
the Universe. Their mind-boggling size makes them incredibly important objects to understand.
Scientists have made important progress in learning about galaxy clusters, but many more
questions and mysteries have emerged. This will keep these objects at the forefront of
astrophysical research for years to come.
Narrator: For more information about the Chandra X-ray Observatory, visit our website at chandra.harvard.edu.