Stardust and Golden



The Guardian carried a great piece yesterday on the two massively dense neutron stars which collided in space 130 million years ago, at a time when dinosaurs still roamed the earth.

It's event like this that remind me why I'm not a religious person or a believer in holy books which insist that a Supreme Being for some reason created our tiny planet, the 'third rock' from the Sun, as the centrepiece of an unbelievably massive universe. 

If you ask me, the singer songwriter Joni Mitchel was nearer the mark when she wrote the words of her famous song Woodstock in which she said:

"We are stardust, we are golden"

Not least because science has at long last proved that heavy elements from the Periodic Table including 'Gold' were created in the furnaces of these fascinating, far off stars before landing on distant planets and being dug out of the ground by human beings many millions of years later.

Which is why I think that Darwinian evolution, the fossil record and the exploration of science are so much more interesting that the fanciful tales contained in the Bible, Quran and so on.

  

https://www.theguardian.com/science/2017/oct/16/astronomers-witness-neutron-stars-collide-global-rapid-response-event-ligo

New frontier for science as astronomers witness neutron stars colliding

Extraordinary event has been ‘seen’ for the first time, in both gravitational waves and light – ending decades-old debate about where gold comes from

By Hannah Devlin - The Guardian

The collision of a pair of neutron stars, marked by ripples through the fabric of space-time and a flash brighter than a billion suns, has been witnessed for the first time in the most intensely observed astronomical event to date.

The extraordinary sequence, in which the two ultra-dense stars spiralled inwards, violently collided and, in all likelihood, immediately collapsed into a black hole, was first picked up by the US-based Laser Interferometer Gravitational-Wave Observatory (Ligo).

As its twin detectors, in Louisiana and Washington state, picked up tremors in space-time that had spilled out from the merger 130m light years away, an alert went out to astronomers across the globe. Within hours, 70 space- and ground-based telescopes swivelled to observe the red-tinged afterglow, making it the first cosmic event to be “seen” in both gravitational waves and light.

Shoemaker was alerted by a ringtone on his phone reserved for when black holes or neutron stars collide

Dave Reitze, executive director of Ligo, said: “What is amazing about this discovery is it is the first time we’ve got a full picture of one of the most violent, cataclysmic events in the universe. This is the most intense observational campaign there has ever been.”

Einstein first predicted the existence of gravitational waves a century ago, but the first experimental proof that space itself can be stretched and squeezed took until 2015, when Ligo scientists detected a collision of black holes. But this dark merger, and the three detected since, were invisible to conventional telescopes.

This time, as the stars collided, they emitted an intense beam of gamma rays and the sky was showered with heavy elements, resolving a decades-old debate about where gold and platinum come from. 



When neutron stars collide

1. Gravitational waves are detected
2. 100 seconds later
Now orbiting at 2,000 times per second and on the brink of colliding, the stars are being distorted by intense gravity
Two neutron stars orbit each other 30 times per second, distorting space and time
Only about 12 miles across, each star is more massive than the sun
3. Two seconds later
4. Afterglow
After the briefest pause, where Ligo could detect nothing, the stars violently merge, emitting a burst of gamma rays
Scientists spot a new light in the sky, the afterglow of the collision, which they are able to identify as the source of the gravitational waves and gamma ray burst
The neutron stars probably collapsed into a black hole
Spectrometers detect heavy elements such as silver and gold

Neutron stars are the smallest, densest stars known to exist: about 12 miles wide, with a teaspoon of neutron star material having a mass of about a billion tons. The core is a soup of pure neutrons, while the crust is smooth, solid and 10 billion times stronger than steel.

The 100-second hum picked up by Ligo told the story of how the two stars, each slightly heavier than the sun, approached their death. Initially separated by 200 miles, they circled each other 30 times a second. As they whirled inwards, accelerating to 2,000 orbits each second, the signal rose in pitch like a slide whistle.

Two seconds later, Nasa’s Fermi space telescope picked up an intense burst of gamma rays, emitted as shockwaves rushed through jets of matter funnelled out of the poles during the monumental impact of the collision.


This animation captures phenomena observed over nine days following the neutron star merger known as GW170817.

What happened next is uncertain. A neutron star weighing more than twice the mass of the sun (the combined mass here) has never been seen before – but neither has a black hole so small. Theoretical predictions suggest an almost instantaneous gravitational collapse into a black hole is most likely.

“Neutron stars are at this sweet spot between a star and a black hole,” said Prof Andreas Freise, a Ligo project scientist at the University of Birmingham. “When two of them collide, we expect them to immediately collapse into a black hole, leaving behind a bit of dust and stuff.”

David Shoemaker, spokesman for the Ligo Scientific Collaboration, said: “It’s [probably] the first observation of a black hole being created where there was none before, which is pretty darn cool.”

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