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LIGO Scientists Spy Neutron Star Smash-Up That Blew Bling Into Space

LIGO Scientists Spy Neutron Star Smash-Up That Blew Bling Into Space

Star corpses collide, explode, and eject heavy elements (like gold) that only the death of stars can create.

neutron star

Sometimes simple questions have complex answers. Case in point: that bling around your neck. Shiny gold, the flesh of the gods, tears of the sun. Where did it come from?

You get zero credit if your answer is “South African mines.” Or “the Big Bang.” The latter created no elements heavier than lithium.

The correct response is colliding neutron stars, a dramatic case of mutually assured destruction that is at the center of one of the day’s biggest science stories. Researchers reported today that the LIGO gravitational wave observatory and its Italian sister, Virgo, picked up yet another twinge in the fabric of space-time last August. This is the fifth since the initial discovery of these subtle perturbations two years ago. But like Sheldon Cooper, this one is a bit of an oddball.

The latest brief ripple wasn’t the death knell of black holes slamming into one another billions of light-years away. It was two neutron stars slamming into one another at a distance of only about 130 millionlight-years. In case you’re new to neutron stars, suffice it to say that they’re the diminutive corpses of large stars — 10 to 30 times as massive as the sun. In a complex process only an astrophysicist could love, these stellar heavyweights die dramatically, going un-gently into that long dark night with a supernova explosion. The leftover remnant is roughly the size of downtown Baltimore, though far denser than Charm City. One teaspoonful would weigh a billion tons. Not appropriate for airline carry-on.

Supernovae belch gravitational waves too. But as vigorous as they are, it’s not clear that LIGO and Virgo could easily detect them. This new event was different. The neutron stars, originally born as massive companions in a double star system, warily circled one another until their dance ended in an explosion a thousand times more energetic than supernovae.

High drama, but there’s more. Gravitational wave telescopes can brag that they’re panoptical — meaning they’ll sense an event no matter which direction it comes from. The downside of this Cyclopean view is that it’s hard to pinpoint the source. Indeed, the LIGO-Virgo apparatus can certify only that this recent event occurred in an area of sky comparable in size to a small constellation. That’s a lot of sky to search, so it’s akin to hearing a shot without knowing where it came from.

But within seconds of the August detection, space-based gamma ray telescopes also registered bursts. Over the next several weeks, 70 optical and radio telescopes were able to pinpoint the source of the commotion — a brightening point of light near the galaxy NGC 4993. In these unremarkable voids, 50 times the distance of the well-known Andromeda galaxy, two unseen neutron stars had squalled their death into the cosmos.

They also made a contribution to humanity. The collision ejected, at ferocious speed, heavy elements like gold, silver, and platinum — materials that only the titanic explosions that mark the death of stars can create.

For years, astrophysicists have speculated that gamma-ray bursts — one of the most energetic of nature’s phenomena and a potential threat to life anywhere — might be due to colliding neutron stars. There’s now greater reason to believe that’s true. Dead stars do tell tales. And the observation is another clue that catastrophes matter. Gradualism doesn’t explain everything about the universe, just as it doesn’t explain everything about the evolution of species.

That bling you’re wearing? It came from a star’s demise, a death so violent it could shake the universe.

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