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Does the Gas in Galaxy Clusters Flow Like Honey?
Coma Cluster
Coma Cluster

  • A new Chandra study has probed the viscosity, or "stickiness," of hot gas in a galaxy cluster.

  • Galaxy clusters are the largest objects in the Universe held together by gravity.

  • Their three main components are hot gas (which gives off X-rays), individual galaxies, and dark matter.

  • Knowledge of gas viscosity in a galaxy cluster helps us understand the effects of important events like mergers with other clusters.

This image represents a deep dataset of the Coma galaxy cluster obtained by NASA's Chandra X-ray Observatory. Researchers have used these data to study how the hot gas in the cluster behaves, as reported in our press release. One intriguing and important aspect to study is how much viscosity, or "stickiness," the hot gas demonstrates in these cosmic giants.

Galaxy clusters are comprised of individual galaxies, hot gas, and dark matter. The hot gas in Coma glows in X-ray light observed by Chandra. Seen as the purple and pink colors in this new composite image, the hot gas contains about six times more mass than all of the combined galaxies in the cluster. The galaxies appear as white in the optical part of the composite image from the Sloan Digital Sky Survey. (The unusual shape of the X-ray emission in the lower right is caused by the edges of the Chandra detectors being visible.)

Despite its abundance, the density of the multimillion-degree gas in Coma, which is permeated by a weak magnetic field, is so low that the particles do not interact with each other very often. Such a low-density, hot gas cannot be studied in a laboratory on Earth, and so scientists must rely on cosmic laboratories such as the one provided by the intergalactic gas in Coma.

The researchers used the Chandra data to probe whether the hot gas was smooth on the smallest scales they could detect. They found that it is not, suggesting that turbulence is present even on these relatively small scales and the viscosity is low.

Why is the viscosity of Coma's hot gas so low? One explanation is the presence of small-scale irregularities in the cluster's magnetic field. These irregularities can deflect particles in the hot gas, which is composed of electrically charged particles, mostly electrons, and protons. These deflections reduce the distance a particle can move freely and, by extension, the gas viscosity.

Knowledge of the viscosity of gas in a galaxy cluster and how easily turbulence develops helps scientists understand the effects of important phenomena such as collisions and mergers with other galaxy clusters, and galaxy groups. Turbulence generated by these powerful events can act as a source of heat, preventing the hot gas in clusters from cooling to form billions of new stars.

A paper describing this research appeared in Nature Astronomy on June 17th, 2019 and is available online. The authors of the paper are Irina Zhuravleva (University of Chicago), Eugene Churazov, (Max Planck Institute for Astrophysics in Garching and the Space Research Institute in Moscow), Alexander Schekochihin (University of Oxford), Steven Allen (Stanford University, SLAC), Alexey Vikhlinin (Harvard-Smithsonian Center for Astrophysics), and Norbert Werner (MTA-Eötvös University Lendulet, Masaryk University, Hiroshima University). NASA's Marshall Space Flight Center in Huntsville, Alabama, manages the Chandra program for NASA's Science Mission Directorate in Washington. The Smithsonian Astrophysical Observatory in Cambridge, Massachusetts, controls Chandra's science and flight operations.

 

Fast Facts for Coma Cluster:
Credit  X-ray: NASA/CXC/Univ. of Chicago, I. Zhuravleva et al, Optical: SDSS
Release Date  June 18, 2019
Scale  Image is about 25 arcmin (2.2 million light years) across.
Category  Groups & Clusters of Galaxies
Coordinates (J2000)  RA 12h 59m 42s | Dec +27° 56´ 40.9"
Constellation  Coma Berenices
Observation Date  36 pointings from March 2008 to March 2017
Observation Time  416 hours 40 minutes (17 days 8 hours 40 minutes)
Obs. ID  9714, 10672, 13993–13996, 14406, 14410, 14411, 14415, 18271–18276, 18761, 18791–18798, 19998, 20010, 20011, 20027–20031, 20037–20039
Instrument  ACIS
References Zhuravleva, I. et al, 2019, Nature Astronomy, arXiv:1906.06346
Color Code  X-ray: purple; Optical: white
Optical
X-ray
Distance Estimate  About 320 million light years (z=0.023)
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