Scientists believe they have resolved a fundamental signature of gravity around a black hole

Using algorithms to peak beneath the glow of a black hole to see light’s last gasp.

Credit: Mark Garlick/Science Photo Library/Getty Images

Have you ever used your hand to shield your eyes from the glare of the Sun so that you can more easily see what’s in front of you?

Recently researchers have done exactly that with images from the Event Horizon Telescope (EHT) of the supermassive black hole at the centre of the M87 galaxy.

In this case, it’s not a physical shield, but an algorithm designed to peel off layers of the original image, which are dominated by the blurry, blobby light coming from gas surrounding the black hole.

“We turned off the searchlight to see the fireflies,” says Avery Broderick, an associate faculty member at the Perimeter Institute and the University of Waterloo, who led the research team.

Based on the current theoretical understanding of how black holes look, the research team was able to build a model for the M87 EHT data and separate out distinct pieces that made up the image as a whole.

By using the algorithm to “peel off elements of the imagery, the environment around the black hole can then be clearly revealed”, says co-author Hung-Yi Pu, assistant professor at National Taiwan Normal University.

These features include the long-sought-after “photon ring”, which is a very thin, bright ring of light tracing the path of photons as they whirl behind the black hole, trapped in the vice grips of the gravity of the central behemoth, like water swirling down a plug hole.

Until now, the photon ring has only been a theoretical prediction.

The technique also revealed the presence of a central jet emanating from the black hole.

“We have been able to do something profound – to resolve a fundamental signature of gravity around a black hole,” says Broderick.

This year saw the release of EHT images of the supermassive black hole (known as Sagittarius A*) at the centre of our own galaxy (the asterisk, pronounced “star” denotes the specific area of Sagittarius A (within the Sagittarius constellation) that houses the supermassive black hole).

Black holes are leaping from the pages of theoretical physics textbooks into our reality at a blinding pace.

Source: Cosmos Magazine