New look at 'Einstein rings' around distant galaxies just got us closer to solving the dark matter debate

Physicists believe most of the matter in the universe is made up of an invisible substance that we only know about by its indirect effects on the stars and galaxies we can see.

We’re not crazy! Without this “dark matter”, the universe as we see it would make no sense.

But the nature of dark matter is a longstanding puzzle. However, a new study^[1] by Alfred Amruth at the University of Hong Kong and colleagues, published in Nature Astronomy, uses the gravitational bending of light to bring us a step closer to understanding.

Invisible but omnipresent

The reason we think dark matter exists is that we can see the effects of its gravity in the behaviour of galaxies. Specifically, dark matter seems to make up about 85% of the universe’s mass, and most of the distant galaxies we can see appear to be surrounded by a halo of the mystery substance.

But it’s called dark matter because it doesn’t give off light, or absorb or reflect it, which makes it incredibly difficult to detect.

So what is this stuff? We think it must be some kind of unknown fundamental particle, but beyond that we’re not sure. All attempts to detect dark matter particles in laboratory experiments so far have failed, and physicists have been debating its nature for decades.

Read more: Why do astronomers believe in dark matter?^[2]

Scientists have proposed two leading hypothetical candidates for dark matter: relatively heavy characters called weakly interacting massive particles (or WIMPs), and extremely lightweight particles called axions. In theory, WIMPs would behave like discrete particles, while axions would behave a lot more like waves due to quantum interference.

It has been difficult to distinguish between these two possibilities – but now light bent around distant galaxies has offered a clue.

Gravitational lensing and Einstein rings

When light travelling through the universe passes a massive object like a galaxy, its path is bent because – according to Albert Einstein’s theory of general relativity – the gravity of the massive object distorts space and time around itself.

As a result, sometimes when we look at a distant galaxy we can see distorted images of other galaxies behind it. And if things line up perfectly, the light from the background galaxy will be smeared out into a circle around the closer galaxy.

This distortion of light is called “gravitational lensing”, and the circles it can create are called “Einstein rings”.

By studying how the rings or other lensed images are distorted, astronomers can learn about the properties of the dark matter halo surrounding the closer galaxy.

Axions vs WIMPs

And that’s exactly what Amruth and his team have done in their new study. They looked at several systems where multiple copies of the same background object were visible around the foreground lensing galaxy, with a special focus on one called HS 0810+2554.

References

1. ^{^} a new study (www.nature.com)
2. ^{^} Why do astronomers believe in dark matter? (theconversation.com)
3. ^{^} Hubble Space Telescope / NASA / ESA (hubblesite.org)
4. ^{^} one study (doi.org)
5. ^{^} another (doi.org)
6. ^{^} Explainer: Standard Model of Particle Physics (theconversation.com)