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  • For thousands of years, people have looked into the night sky and found stuff they didn't understand.

  • That's kind of how astronomy happened.

  • But not very many of those mysteries have lasted for a hundred years.

  • And even if they have, most of them aren't as simple aswhat am I even looking at?”

  • Then, there are the diffuse interstellar bands.

  • These are patterns of light in space that don't match any known atom or molecule.

  • There are hundreds of them, and we've been trying to figure out what they are for nearly a century.

  • After decades of work, scientists finally identified one of these bands in 2015,

  • but even then, it's just downright bizarre: a cage-like carbon molecule containing sixty atoms.

  • So what else is floating around out there?

  • The diffuse interstellar bands, or DIBs, were first uncovered in 1919 by astronomer Mary Lea Heger.

  • She was studying faraway stars by measuring their spectra,

  • or the distribution of their light by wavelength.

  • Different molecules absorb and emit different types of light,

  • so patterns in these readings typically tell astronomers what objects are made of.

  • But this time, Heger noticed a pattern that had never been seen before,

  • and it wasn't clear which molecules were the culprits.

  • Their light absorption showed up as fuzzy gaps, or diffuse bands in spectra taken with early photographic plates,

  • so these signals quickly picked up a nickname.

  • But it wasn't like astronomers had never found strange readings before.

  • In 1868, the observation of an unknown spectral band in the Sun's atmosphere

  • had actually led to the discovery of helium.

  • It's science: New stuff comes up all the time.

  • The weird part with DIBs is what happened next: nothing.

  • Scientists were unable to find any matching atom or molecule here on Earth.

  • In fact, they still haven't, at least, for those specific signals.

  • Instead, over the next century, astronomers found nearly 500 more DIBs.

  • And until 2015, they hadn't explained a single one.

  • That year, a team of physicists were messing around with an exotic molecule called buckminsterfullerene.

  • Rather than repeating that word over and over, people usually just call them buckyballs,

  • but they are not the same stuff as the popular magnetic toys.

  • Buckyballs had been discovered during lab experiments in the 1980s

  • designed to simulate the gas flowing out of carbon-rich stars.

  • They're made of 60 linked carbon atoms, look remarkably similar to a soccer ball,

  • and were cool enough to earn their discoverers the 1996 Nobel Prize in Chemistry.

  • The 2015 experiment cooled down a gas of buckyballs to nearly absolute zero and an ultralow pressure,

  • essentially, the conditions of deep space.

  • And in that situation, the researchers found

  • that buckyballs emit a spectrum of light that matched a set of diffuse interstellar bands discovered in 1994.

  • Which was awesome!

  • It meant we finally had at least one answer about these signals.

  • Researchers think these molecules may be formed in the atmosphere of a carbon-rich star.

  • Then, they could be carried into space as part of the star's stellar wind,

  • where they might survive for millions of years.

  • Whenever that gas floats between us and another star, it absorbs a bit of that star's light,

  • and leaves behind its imprint in the form of a DIB.

  • So what about all the other diffuse bands?

  • Well, many researchers are investigating molecules that contain carbon as potential culprits.

  • Carbon is capable of forming four strong chemical bonds,

  • which allows it to anchor the largest and most diverse collection of molecules in nature.

  • And it's been a promising lead so far.

  • Besides buckyballs, we now think some DIBs are probably created by other fullerenes,

  • the category of large, cage-like carbon molecules that buckyballs belong to.

  • Complex molecules like these can come in a bunch of forms that are only slightly different from each other,

  • but each of those tiny variations may be enough to create a new diffuse band.

  • Other DIBs might come from a different class of large carbon molecules:

  • the polycyclic aromatic hydrocarbons.

  • They're large, net-like structures of carbon and hydrogen that astronomers know are common throughout the universe.

  • But just focusing on carbon doesn't mean it will be easy for scientists to match more molecules with DIBs.

  • Unfortunately, it'll probably be slow going.

  • To get a spectrum, chemists and physicists have to recreate the conditions of deep space in the lab.

  • That process is both really hard and a little different for every substance.

  • And I'm not a professional scientist,

  • but that combination frankly doesn't sound that fun.

  • To top it all off, there's a virtually unlimited number of potential molecules,

  • which isn't the best situation when you're essentially doing guess-and-check.

  • For now, it seems likely that astronomers will keep finding new DIBs faster than lab scientists can explain them.

  • There is, however, a silver lining: Each new, unexplainable band is a sign that an unknown,

  • maybe even undiscovered molecule is floating out there in the cosmos.

  • And that's pretty cool.

  • A little unnerving for researchers maybe, but cool.

  • Thanks for watching this episode of SciShow Space!

  • If you'd like to learn about another mystery in the world of astronomy and planetary science,

  • you can watch our episode about the Hypatia stone.

  • [ ♪ Outro ]

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