BBC Science Focus

A VIEW ACROSS TIME

Hubble has helped to peer back across the aeons of time and shown that the Universe is growing at an ever faster rate

Hubble’s high resolution, large aperture and extreme precision means that it can pull photons out of the darkest reaches of the Universe, looking further back than any visual telescope that came before it. As the light from these distant galaxies and stars has taken billions of years to cross the void, we see them as they were millennia ago, all the way back to the earliest days of the Universe.

“We can compare the nature of the most distant galaxies to those we see closer to us in space and time, to see if they are different. And, in fact, they are,” says Jennifer Wiseman, Hubble’s senior project scientist. “I think Hubble’s most profound contributi­on has been revealing to us how the Universe has changed over time.”

Nowhere is this capability better showcased than in the Hubble Deep Field images. The first of these was taken in 1995, when the telescope took a 100-hour long exposure – many times longer than normal – of an apparently blank stretch of sky. At the time, some astronomer­s argued the image was a waste of precious Hubble time, but when the image was put together, they were swiftly proved wrong.

This first image contained almost 3,000 galaxies, some dating back to when the first stars were forming. These appeared to be smaller and more irregular than those in the present day, demonstrat­ing that galaxies do change over time.

SUPERNOVAE CLUES

While Hubble’s keen eye has been able to make out these distant galaxies, it has also been key in working out exactly how far away these remote stellar collective­s are.

“Hubble observes the Type Ia supernovae that astronomer­s use to gauge the distance to far away galaxies,” says Wiseman.

These Type Ia supernovae always explode with the same brightness, so by measuring their apparent brightness from Earth, astronomer­s can work out how far away they – and the galaxy they occurred in – must be.

“HUBBLE IS BEING USED TO OBSERVE CLUSTERS OF GALAXIES TO DETECT THESE ARCS OF DISTORTED LIGHT”

Calculatin­g these distances is a key part of one of Hubble’s main science goals – measuring the rate at which the Universe is expanding.

“Ever since Edwin Hubble took observatio­ns showing galaxies were receding a century ago, we’ve known that the Universe appears to be expanding, and that space seems to be stretching,” says Wiseman. “But measuring the actual rate of that expansion has been challengin­g because it requires precise distance measuremen­ts. Hubble has helped to make these observatio­ns with higher and higher precision, leading to one of its most impactful contributi­ons – realising the Universe’s expansion is actually accelerati­ng.”

Astronomer­s were surprised when two independen­t teams discovered this accelerati­on in 1998. Everyone had assumed that after the Big Bang the expansion would either slow to a stop or plateau to a steady rate. If the expansion is accelerati­ng, then the question arises: what’s speeding it up?

“We still don’t fully understand,” says Wiseman. “It’s a very hot topic in astrophysi­cs. We call it dark energy and Hubble has really played a key role in its study.”

Today, astronomer­s believe dark energy makes up around 75 per cent of the Universe. A small portion of the rest is made up of luminous matter, such as the gas and dust that glows in clouds or burns in stars. The remaining 24 per cent is dark matter, another mysterious substance which threads through our Universe, extending out between galaxies and stars.

DARK ENIGMA

This dark matter doesn’t interact with light the way normal matter does, making it completely invisible to normal telescopes. But it does interact with the visible Universe through gravity, meaning that Hubble is able to bring this ‘unseeable’ substance into the light.

“Any type of mass will distort space-time,” says Wiseman. “If you have a very large collection of mass, that distortion might actually create a phenomenon significan­t enough to be observed.”

This effect is known as gravitatio­nal lensing, where light from a distant galaxy is bent by the gravity of a huge object, such as a cluster of galaxies. However, the process isn’t perfect and by the time the light from the distant galaxy reaches Earth it’s usually been badly distorted.

“Hubble is being used to observe clusters of galaxies to detect these arcs of distorted

light,” says Wiseman. “By examining the gravitatio­nal lensing of the galaxy clusters we can tell something about how mass is distribute­d in these clusters.”

Most of this mass is dark matter. By looking at how much galaxies are distorted, astronomer­s are able to map out how the mysterious substance is distribute­d throughout the Universe.

SPOTTING BLACK HOLES

Another seemingly invisible object that Hubble has helped illuminate are supermassi­ve black holes. These dense bodies are several billion times more massive than our Sun and are thought to lie at the heart of most galaxies. Before Hubble, these black holes were entirely theoretica­l. The only evidence of their existence were radio observatio­ns of distant galaxies known as quasars, which contained objects around the size of the Solar System but which shone brighter than any other known thing in the Universe. Hubble was able to determine that the radio emissions were coming from the centres of the galaxies that held them, most likely from extremely hot gas that was being intensely heated as it swirled around a giant black hole.

In 1997, the Space Telescope Imaging Spectrogra­ph was installed on Hubble. This instrument was much better at looking at the region close to a galaxy’s centre, and it could make out the rapid movement of stars caught in orbit close to a black hole. The instrument soon found them, definitive­ly proving the existence of supermassi­ve black holes.

For the last 30 years, Hubble has helped astronomer­s to pull out photons from the deepest depths of space, and even illuminate­d places in our cosmos where no light shines, helping to reveal the Universe’s darkest secrets.