Two galaxy clusters collided, creating a massive shock wave stretching out over 1.6 million light-years long. NASA’s Chandra X-ray Observatory spotted the shock wave earlier this month. NASA says that these galactic collisions unleash vast amounts of energy. Additionally, it could help us better understand some of the physics that make up our solar system.

Galactic collisions are leading to intriguing research

Researchers are publishing a new study on these colossal galactic collisions in The Monthly Notices of the Royal Astronomical Society. The paper is currently viewable on the arXiv preprint server. In it, researchers detail how these collisions unleash their energy and create “collisionless shockwaves” that can travel millions of light-years away.

While the idea of a collisionless shock wave might sound impossible, especially as we talk about colliding galaxy clusters, it is important to note that just because two clusters are crashing into each other doesn’t mean a physical collision is happening. Galaxy clusters are made up of more than just the galaxies within them.

In fact, the majority of a galactic cluster is an immense halo of dark matter and a cloud of gas known as the intra-cluster medium. It’s these two components that often cause the collisionless shock waves that scientists have been studying. It’s also these components that often crash together within galactic collisions like the one in Abel 2146.

Crashing together

galactic collisions in abell 2146Image source: X-ray: NASA/CXC/Univ. of Nottingham/H. Russell et al.; Optical: NAOJ/Subaru

It’s the way that these two components crash together that has scientists intrigued. And, some say, it could help us better understand the physics that drive our universe. For starters, in the galactic collision in Abel 2146, one cluster is falling through the other one. As it does so, it’s creating two shock waves, a bow shock, and an upstream shock.

Researchers say the galactic collision’s bow shock is compressed gas ahead of the infalling cluster. However, the upstream shock is much more complex. Instead, it forms when the gas that is removed from the infalling cluster is left behind and interacts directly with the in-situ gas within the cluster it’s moving through.

It’s these reactions that have created the collisionless shock waves that Chandra has been observing. Additionally, it is the bow shock wave that measures 1.6 million light-years long. The researchers also measured the width of the shock wave for the first time. They confirmed theories that the upstream shock is narrower than the bow shock because it is younger.

Further, NASA says that understanding these shock waves could also help us better understand the outbursts that our Sun releases.

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