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Science

Astronomers Find Rare Star System That Will Trigger a Kilonova

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An artist’s rendition of the binary stay system, called CPD-29 2176.
Illustration: Noir Lab

The universe has no shortage of oddities, and researchers at the National Science Foundation’s NOIRLab have observed another one in the form of a particular binary star system. The system, called CPD-29 2176, will eventually trigger a kilonova, a celestial event in which two neutron stars collide in a massive explosion that forms heavy elements, including gold and platinum.

CPD-29 2176 is located around 11,400 light-years from Earth and was found by researchers using NASA’s Neil Gehrels Swift Observatory. Astronomers then conducted more observations at NOIRLab’s Cerro Tololo Inter-American Observatory in Chile. CPD-29 2176 is home to one neutron star and one massive star that is in the process of going supernova, only to become a second neutron star in the future. Eventually, the two neutron stars will collide, producing a kilonova, an explosion that is thought to produce bursts of gamma rays and large amounts of gold and platinum. The paper documenting the research team’s find is published today in Nature.

“We know that the Milky Way contains at least 100 billion stars and likely hundreds of billions more. This remarkable binary system is essentially a one-in-ten-billion system,” said André-Nicolas Chené in a NOIRLab press release. Chené is a NOIRLab astronomer and an author on the study. “Prior to our study, the estimate was that only one or two such systems should exist in a spiral galaxy like the Milky Way.”

While many stars implode was a powerful supernova when they die, the dying star in CPD-29 2176 is becoming an ultra-stripped supernova. An ultra-stripped supernova lacks the vast amount of force that a typical supernova has, since the dying star has had much of its mass stripped by its companion. The researchers think that the neutron star in the system was also formed with an ultra-stripped supernova and argue that this is the reason that CPD-29 2176 is able to remain as a binary—a typical supernova would have enough power to kick a companion star out of its orbit.

“The current neutron star would have to form without ejecting its companion from the system. An ultra-stripped supernova is the best explanation for why these companion stars are in such a tight orbit,” said lead author Noel D. Richardson, a physics and astronomy professor at Embry-Riddle Aeronautical University, in the NOIRLab release. “To one day create a kilonova, the other star would also need to explode as an ultra-stripped supernova so the two neutron stars could eventually collide and merge.”

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It will take around one million years for the star undergoing ultra-stripped supernova to turn into a neutron star. It is then when the two stars will begin to spiral into each other, eventually resulting in the metal-producing kilonova, according to the research. In these dramatic cosmic endings, we can look forward to the creation of the same elements that make life possible.  

More: Watch Four Planets Spin Around a Star 130 Million Light-Years Away

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Science

This Blasted Star Is Getting the Hell Out of the Milky Way

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Careening through the Milky Way at nearly 2 million miles per hour, the star LP 40–365 shows no signs of stopping. A team of astronomers recently figured out that the star was propelled into its current speedrun by a supernova explosion millions of years ago.

LP 40–365 is unusual. It’s a white dwarf, a small, compact star at the end of its life, and it’s very rich in metals. LP 40–365 also has own atmosphere, which is mostly composed of oxygen and neon. But most important to this story is that the star is a runaway from a huge stellar explosion, which set in motion its dash out of the galaxy.

When a white dwarf is orbiting another (in what’s called a white dwarf binary), one star gives up mass to the other, which gobbles it up steadily. The binaries can also emit gravitational waves—perturbations in spacetime—as they orbit one another, with the hungry star (the accretor) in the duo detonating in a huge thermonuclear explosion.

The team behind the new research isn’t sure whether stars like LP 40–365 are typically the donors or the accretors in their white dwarf binary systems, but they believe this particular hot metal ball is basically stellar shrapnel from the accreting star, which eventually exploded in fantastic fashion. Their findings were published this week in The Astrophysical Journal Letters.

“To have gone through partial detonation and still survive is very cool and unique, and it’s only in the last few years that we’ve started to think this kind of star could exist,” Odelia Putterman, a researcher now at Occidental College and a co-author of the paper, told The Brink, a publication of Boston University.

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The team found the star using observations from the Transiting Exoplanet Survey Satellite (TESS) and the Hubble Space Telescope, which turned up a fast-moving object with a regular pattern of dimming and brightening. That suggested the star was slowly rotating—completing its rotation every nine hours—as it hurtled through space. That’s a pretty slow rotation rate, and weird to think about in conjunction with how fast the star is moving through space. It’s from that rotation rate that the team figures the white dwarf is the remnant of one star in a binary system collapsing in on itself, blasting its partner and all else in the area outwards at extraordinary speed. Based on the team’s calculations, they believe LP 40–365 has been traveling from its origin galaxy for a little over 5 million years.

“The star is basically being slingshotted from the explosion, and we’re [observing] its rotation on its way out,” Putterman told The Brink .

More: Astronomers Think They’ve Spotted a Rare Kind of Supernova Only Predicted to Exist

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