Categories: Cosmology

Study of 200,000 Galaxies Reveals the Entire Universe Might Have Been Spinning in One Direction Early On

Some of the most dramatic events in the Universe occur when certain stars die — and explode catastrophically in the process. Such explosions, known as supernovae, mainly occur in a couple of ways: either a massive star depletes its fuel at the end of its life, become dynamically unstable and unable to support its bulk, collapses inwards, and then violently explodes; or a white dwarf in an orbiting stellar couple syphons more mass off its companion than it is able to support, igniting runaway nuclear fusion in its core and beginning the supernova process. Both types result in an intensely bright object in the sky that can rival the light of a whole galaxy. In the last 20 years the galaxy NGC 5468, visible in this image, has hosted a number of observed supernovae of both the aforementioned types: SN 1999cp, SN 2002cr, SN2002ed, SN2005P, and SN2018dfg. Despite being just over 130 million light-years away, the orientation of the galaxy with respect to us makes it easier to spot these new ‘stars’ as they appear; we see NGC 5468 face on, meaning we can see the galaxy’s loose, open spiral pattern in beautiful detail in images such as this one from the NASA/ESA Hubble Space Telescope.

Almost everything in the universe spins. Planets rotate on their axis, stars spin around black holes, and galaxies spin in great spiral structures. But what about the universe as a whole?

Structures rotate because of a property known as angular momentum. Angular momentum is a measure of mass and rotation, and it is a conserved physical property. One of its characteristics is that when mass moves closer together, it spins faster to keep angular momentum constant. You see this in figure skaters when they leap into the air and pull their limbs close to their bodies. Galaxies, stars, and planets all formed from great clouds of cosmic gas and dust. As gravity caused these clouds to collapse, even the smallest bit of rotation was amplified. So it is natural that they all spin.

But on a cosmic scale, things are different. It’s generally thought that the universe is homogeneous and isotropic. This means that on average matter should be evenly spread out and that the total angular momentum of the cosmos should be about zero. If that’s true, then the rotation of galaxies should be random. In any region of space you look, about half should be spinning in a clockwise direction, and about half anticlockwise.

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Bias in galaxy spin directions on a cosmic scale. Credit: Lior Shamir

But there is some evidence that galactic rotation isn’t homogeneous. In 2011, a study of 15,000 galaxies found that there was a small bias in rotation. Because of the relatively small sample size, the evidence was somewhat weak. But this week a paper was presented at the 236th American Astronomical Society meeting, which showed an even stronger bias.

It’s important to note that this work has not yet been peer-reviewed, so we should be cautious about the conclusions. The study looked at 200,000 galaxies and their measured rotations. With the larger sample size, it found not only a rotational bias but also some of its cosmological properties. For one, the bias seems to get stronger with greater redshift. At ever-larger scales the bias is harder to ignore.

The cold spot seen in the cosmic microwave background. Credit: ESA Planck Collaboration

This supports the idea that the universe as a whole has an axis of rotation. Interestingly the cosmic axis seems to align with the so-called cold spot of the cosmic microwave background. While that’s interesting, we probably shouldn’t read too much into it. For one thing, the data doesn’t support a simple, single axis of rotation, such as that of a planet or star. Instead, the bias has a more complicated multipole structure.

All that said, there does seem to be something strange going on. While the universe does seem to be approximately homogeneous and isotropic, studies such as this are hinting that it isn’t exact. While that might not seem like a big deal, it has huge implications for our cosmological models.

Reference: Longo, Michael J. “Detection of a dipole in the handedness of spiral galaxies with redshifts z? 0.04.” Physics Letters B 699.4 (2011): 224-229.

Reference: Shamir, L. “Distribution of galaxy spin directions in Pan-STARRS and SDSS shows large-scale multipoles and redshift dependence.” 236th AAS Meeting (virtual) 336.02, 2020.

Brian Koberlein

Brian Koberlein is an astrophysicist and science writer with the National Radio Astronomy Observatory. He writes about astronomy and astrophysics on his blog. You can follow him on YouTube, and on Twitter @BrianKoberlein.