Structures in the cosmic mist

The Milky Way has existed for at least 13 billion years. Since then, it has continued to produce more and more new stars; one generation gives way to the next. To do this, it needs gas – more than it contains itself. That applies to all other galaxies too. But where do the Milky Way, Andromeda, and their like find more gas? In the intergalactic medium, which, at first glance, looks like just empty space between the galaxies.

But these gigantic areas are not empty. They contain the intergalactic medium, mostly baryons (up to 80-90 percent, if the Big Bang theory is correct). This is matter that is not influenced by any system through gravity. However, as shown in a new study by an international research team, this matter is forming structures. Normally, the intergalactic medium (IGM) can only be observed indirectly – by the blocking effect it has on radiation from stars located behind the IGM. The researchers therefore selected to simulate the medium. In the computer simulation, they let two halos of matter (each surrounding a galaxy) interact across a megaparsec-long cosmic filament and observed the resulting structures.

The results surprised the astronomers. In the IGM, at first, flat, pancake-like structures formed, which extended over many millions of light-years. But the gas was also not uniformly arranged in these pancakes. Instead, small, discrete bubbles of relatively dense and cold (that is, non-ionized) gas formed like condensation nuclei in clouds. It was previously assumed that such structures could be produced due to the effects of being close to a galaxy but apparently it can also occur far away in the cosmic backwoods as a result of very efficient cooling of the gas. The researchers compared the process to the formation of mist in humid air. The discovery might explain why astronomers have recently discovered several dense, metal-free clouds of matter right in the middle of the IGM.

The image shows the gas temperature in the IGM. Red is hot gas; blue is cold gas. We are in the middle of the simulation; the number of bubbles has increased. (image: Yale University)
The image shows the gas temperature in the IGM. Red is hot gas; blue is cold gas. We are at the start of the simulation. (image: Yale University)

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  • BrandonQMorris
  • Brandon Q. Morris is a physicist and space specialist. He has long been concerned with space issues, both professionally and privately and while he wanted to become an astronaut, he had to stay on Earth for a variety of reasons. He is particularly fascinated by the “what if” and through his books he aims to share compelling hard science fiction stories that could actually happen, and someday may happen. Morris is the author of several best-selling science fiction novels, including The Enceladus Series.

    Brandon is a proud member of the Science Fiction and Fantasy Writers of America and of the Mars Society.