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  • We have a pretty good understanding of how a lot of elements in the periodic table formed.

  • Hydrogen, Helium and Lithium, the three lightest elements, formed shortly after the big bang.

  • Heavier elements, up to Iron, were forged billions of years later in the hearts of stars.

  • But the origin of the naturally occurring elements heavier than iron is less certain.

  • That was until October of 2019, when researchers analyzing data from a neutron star collision

  • announced they were certain how about half of those heavier elements form.

  • They witnessed something called the rapid neutron capture process, or r-process, which

  • was first proposed about 60 years ago.

  • It was thought to occur only in extreme environments where atoms were bombarded with huge numbers

  • of neutrons.

  • This allows the atom's nucleus to capture neutrons quicker than it can decay, forming

  • a heavier element.

  • But we couldn't confirm where in the universe would bombard elements with enough neutrons

  • to make the r-process possible.

  • Now I realize I may have spoiled the big reveal here when I said that scientists figured it

  • out after watching neutron stars collide.

  • After all, where are you going to find more NEUTRONS than when two NEUTRON stars crash

  • into each other?

  • Aside from that episode where Jimmy Neutron cloned himself a whole bunch.

  • But the truth is scientists weren't certain neutron stars had, um, neutrons in them.

  • We were pretty sure that's what's left over after massive stars go supernova and

  • their surviving cores are dense enough to crush protons and electrons together yet not

  • dense enough to further implode and become a black hole.

  • But we weren't 100% sure.

  • Then, in 2017, scientists caught a break.

  • Gravitational wave detectors LIGO and Virgo sensed waves coming from somewhere in the

  • southern sky.

  • About two seconds later, two instruments detected a gamma ray burst from the same area.

  • These phenomena together tipped off scientists that a neutron star merger and it's predicted

  • explosive aftermath called a kilonova was likely occurring.

  • Telescopes scrambled to find the source, until they spotted a new point of light about 130

  • million light years away.

  • One instrument in particular, the European Southern Observatory's X-Shooter, studied

  • the kilonova for days, recording its spectrum from ultraviolet to the near infrared.

  • By analyzing the spectrum, scientists could look for the distinct fingerprint elements

  • leave as they absorb parts of the spectrum.

  • But at first the heavier elements weren't easy to suss out, because their spectrums

  • can create complex blends of tens of millions of spectral lines, making them hard to tell

  • apart.

  • It wasn't until scientists reexamined the data that they spotted a distinct line at

  • the boundary of visible light and infrared.

  • This 810 nm spectroscopic feature told the scientists they witnessed the creation of

  • the heavy element strontium through rapid neutron capture.

  • What's surprising about spotting strontium is it's actually one of the lighter of the

  • heavy elements formed by the r-process.

  • In order for it to occur, neutrinos have to bombard neutrons to break them down into protons

  • and electrons.

  • Strontium's discovery told astronomers that a wide range of heavy elements form during

  • kilonovae, from the lighter to the very heaviest.

  • The discovery of strontium hiding among the kilonova's spectrum filled in several gaps

  • in our knowledge.

  • It confirms the r-process takes place when neutron stars merge, and shows conclusively

  • that neutron stars in fact contain neutrons.

  • Not a bad day's work, but the science is never finished.

  • Next the researchers will look to expand their knowledge of the spectral lines of heavier

  • elements, hoping to conclusively identify more products of the neutron star collision.

  • In case you were wondering, there is also a slow neutron capture process, or s-process,

  • which is thought to occur in the outer layers of old stars and is responsible for the other

  • half of heavy elements.If you like our Elements episodes you may also enjoy our Focal Point

  • series.

  • Check out this episode on a clock that could redefine time.

  • Also, be sure to subscribe to Seeker,

  • and don't forget to keep coming back

  • for more science content in your day.

  • I'll see you next time!

We have a pretty good understanding of how a lot of elements in the periodic table formed.

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科学者たちが宇宙で重元素の誕生を目撃 (Scientists Just Witnessed the Birth of a Heavy Element in Space)

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    林宜悉 に公開 2021 年 01 月 14 日
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