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Celebrating 10 Years of Suzaku: Outskirts of Clusters of Galaxies

Celebrating 10 Years of Suzaku
Outskirts of Clusters of Galaxies

optical image of the Perseus cluster of galaxies /

The Perseus galaxy cluster contains 190 galaxies and lies about 225 million light-years away. (Credit: Robert Lupton and the Sloan Digital Sky Survey Consortium)

Long before Suzaku launched in 2005, scientists knew that clusters of galaxies were filled with hot, X-ray emitting gas. The combined gravity of the cluster keeps the hot gas from escaping, and we can estimate how much mass is needed to keep the gas within the cluster. It turns out that the stars that make up the member galaxies add up to just a small fraction of the total mass. The X-ray emitting gas itself is a more significant part of the story. But the main source of the gravity is dark matter.

In fact, galaxies and clusters of galaxies are believed to form from normal matter attracted by clumps of dark matter, which in turn grew out of small fluctuations in density in the early universe. Clusters of galaxies can grow by merging with each other or by accreting smaller clumps. Studies of the formation and growth of large scale structures such as clusters are an active area of research today. In theoretical studies, dark matter, mysterious it is, is easier to deal with: you only have to consider its gravitational effects, by definition. The behavior of normal matter is far more complex. They form stars, which creates heavier elements from hydrogen and helium. Some stars explode as supernovae, dispersing newly created elements which are heated by collisions with nearby interstellar matter. Stars, supernovae, and supermassive black holes at the centers of galaxies produce a lot of electromagnetic radiation, which can push around normal matter.

You can learn a lot about this process by observing clusters of galaxies in the X-rays. Such studies naturally started with places where the X-ray glow is the most intense. That's the central region of clusters, since X-ray emission is proportional to the square of the density, and the densest part of clusters is the central region. If that's all you can do, you have to worry if you might be missing something important. Before Suzaku entered the picture, that was the case, with typical Chandra and XMM-Newton observations of clusters being able to study only about 30% of the volume of clusters of galaxies. It turns out that, while these flagship missions have exquisite sensitivities for point-like sources of X-rays, Suzaku is better suited to studies of the diffuse, faint glow of X-rays from the outskirts of clusters. Both in-depth studies of individual clusters and comparisons of clusters with different physical properties have been performed using Suzaku data and produced new insights. One cluster in particular, Perseus, has been observed at many locations because this is the nearest brightest cluster.

Here are three noteworthy discoveries by Suzaku featuring galaxy clusters.

X-ray emission from cluster PKS 0745-191

This Suzaku image shows X-ray emission from hot gas throughout the galaxy cluster PKS 0745-191. (Credit: NASA/ISAS/Suzaku/M. George, et al.)

First Complete X-ray View of a Cluster of Galaxy

This paper published in 2009 was the first to demonstrate that Suzaku data can be used to study these tenuous X-ray emitting gas in the outskirts of clusters of galaxies. More than the specific findings, this paper is noteworthy for opening a new sub-field of X-ray astronomy that became arguably the most important contribution of Suzaku.

Suzaku observations of the Perseus cluster

Suzaku's observations across two swaths of the Perseus Galaxy Cluster. (Credits: NASA/ISAS/DSS/A. Simionescu et al.; inset: NASA/CXC/A. Fabian et al.)

Clumping in the outskirts of the Perseus cluster

A team of scientists studied the characteristics of the X-ray emitting gas in the Perseus cluster of galaxies from the center to the outer edge in two directions. Their results are best understood if the gas is clumpy in the outer regions of this cluster. Numerical simulations show that freshly infalling gas tends to fall irregular clumps, but this result indicates that the clumps are not immediately destroyed.

Suzaku observations of the Perseus cluster

Suzaku explored faint X-ray emission along eight different directions in the Perseus Galaxy Cluster. (Credit: NASA/ISAS/DSS/O. Urban et al., MNRAS)

Early Cosmic Seeding

Follow-up study of the Perseus cluster, now using Suzaku data from center to the outer edge in 8 directions, showed that the fraction of iron in the X-ray emitting gas ("iron abundance") is remarkably uniform across the cluster. Iron is mostly from Type Ia supernovae – such uniform iron abundance indicates that iron was created in Type Ia supernova before the cluster formed.

*Tell me more about clusters of galaxies

*Tell me more about dark matter

Publication Date: July 2015


A service of the High Energy Astrophysics Science Archive Research Center (HEASARC), Dr. Alan Smale (Director), within the Astrophysics Science Division (ASD) at NASA/GSFC

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