Gold origin confirmed with first ever gravitational wave sighting

October 16, 2017, University of Warwick
Artist's impression of merging neutron stars. Credit: University of Warwick/Mark Garlick

Gold's origin in the Universe has finally been confirmed, after a gravitational wave source was seen and heard for the first time ever by an international collaboration of researchers, with astronomers at the University of Warwick playing a leading role.

Members of Warwick's Astronomy and Astrophysics Group, Professor Andrew Levan, Dr Joe Lyman, Dr Sam Oates and Dr Danny Steeghs, led observations which captured the light of two colliding , shortly after being detected through gravitational waves - perhaps the most eagerly anticipated phenomenon in modern astronomy.

Huge amounts of gold, platinum, uranium and other heavy elements were created in the collision of these compact stellar remnants, and were pumped out into the universe - unlocking the mystery of how gold on wedding rings and jewellery is originally formed.

The collision produced as much gold as the mass of the Earth.

This discovery has also confirmed conclusively that short gamma-ray bursts are directly caused by the merging of two neutron stars.

The neutron stars were very dense - as heavy as our Sun yet only 10 kilometres across - and they collided with each other 130 million years ago, when dinosaurs roamed the Earth, in a relatively old galaxy that was no longer forming many stars.

They drew towards each other over millions of light years, and revolved around each other increasingly quickly as they got closer - eventually spinning around each other five hundred times per second.

Their merging sent ripples through the fabric of space and time - and these ripples are the elusive gravitational waves spotted by the astronomers.

The were detected by the Advanced Laser Interferometer Gravitational-Wave Observatory (Adv-LIGO) on 17 August this year, with a short duration gamma-ray burst detected by the Fermi satellite just two seconds later.

This led to a flurry of observations as night fell in Chile, with a first report of a new source from the Swope 1m telescope.

Longstanding collaborators Professor Levan and Professor Nial Tanvir (from the University of Leicester) used the facilities of the European Southern Observatory to pinpoint the source in infrared light.

Professor Levan's team was the first one to get observations of this new source with the Hubble Space Telescope. It comes from a galaxy called NGC 4993, 130 million light years away.

Andrew Levan, Professor in the Astronomy & Astrophysics group at the University of Warwick, commented: "Once we saw the data, we realised we had caught a new kind of astrophysical object. This ushers in the era of multi-messenger astronomy, it is like being able to see and hear for the first time."

Dr Joe Lyman, who was observing at the European Southern Observatory at the time was the first to alert the community that the source was unlike any seen before.

He commented: "The exquisite observations obtained in a few days showed we were observing a kilonova, an object whose light is powered by extreme nuclear reactions. This tells us that the heavy elements, like the gold or platinum in jewellery are the cinders, forged in the billion degree remnants of a merging neutron star."

Dr Samantha Oates added: "This discovery has answered three questions that astronomers have been puzzling for decades: what happens when neutron stars merge? What causes the short duration ? Where are the , like gold, made? In the space of about a week all three of these mysteries were solved."

Dr Danny Steeghs said: "This is a new chapter in astrophysics. We hope that in the next few years we will detect many more events like this. Indeed, in Warwick we have just finished building a telescope designed to do just this job, and we expect it to pinpoint these sources in this new era of multi-messenger astronomy".

Explore further: Astronomers first to see source of gravitational waves in visible light

Related Stories

Seeing the light of neutron star collisions

October 16, 2017

When two neutron stars collided on Aug. 17, a widespread search for electromagnetic radiation from the event led to observations of light from the afterglow of the explosion, finally connecting a gravitational-wave-producing ...

What are neutron stars?

October 16, 2017

Thrilled physicists and astronomers announced Monday the first-ever observation of the merger of two neutron stars, one of the most spectacularly violent phenomena in the Universe.

Explainer: Why gravitational wave researchers won a Nobel

October 3, 2017

Three U.S.-based astrophysicists won the Nobel prize in physics Tuesday for their discovery of gravitational waves, a phenomenon Albert Einstein predicted a century ago in his theory of general relativity. Here's what their ...

Recommended for you

3 comments

Adjust slider to filter visible comments by rank

Display comments: newest first

Solon
1 / 5 (3) Oct 16, 2017
"You can fool all the people some of the time, and some of the people all the time, but you cannot fool all the people all the time."

Most here are fools, it seems.
RealScience
5 / 5 (4) Oct 16, 2017
Two bodies each the mass of the sun, circling each other hundreds of time per second, is awe inspiring!
katesisco
1 / 5 (2) Oct 17, 2017
I rather suspect that Pierre-Marie Robitaille's proposal that stars change their lattices and become different kinds of stars is more likely to produce metals ejected from the equator of the star. NASA paper A Star With Two North Poles notes how a star---our sun Sol---can transform its charge sheath--the heliosphere. https://www.nasa....les.html

Please sign in to add a comment. Registration is free, and takes less than a minute. Read more

Click here to reset your password.
Sign in to get notified via email when new comments are made.