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  • [♪ INTRO]

  • Meteorites hold a special place in astronomy

  • because they represent basically the only part of the universe beyond Earth that we can actually touch.

  • Every one has a story to tell, but some of those tales are more curious than others.

  • So here are 3 of the weirdest meteorites we've ever found and what we learned from them.

  • Our first example isn't actually just one meteorite, but a whole category.

  • About a quarter of all meteorite samples show certain distinctive signs

  • of being sculpted by the atmosphere as they fell to Earth.

  • The most striking have a special cone-like shape

  • scientists call oriented meteorites.

  • After the white-hot intensity of hurtling through Earth's atmosphere,

  • most meteorites end up looking like weird chunks of rock.

  • But the oriented ones are kind of comparable to the conical nose of an airplane,

  • you can tell which way they were pointed as they fell.

  • Astronomers have known about oriented meteorites for a long time,

  • but they didn't really know how this cone shape formed or why it only happens some of the time.

  • But a paper published in 2019 has finally shed some light on the situation.

  • The researchers recreated the flight of a meteorite.

  • But instead of using a lump of rock falling through the sky, they used lumps of aluminum falling through water.

  • And cone-shaped lumps tended to fall in a relatively straight path without fluttering or tumbling.

  • This tells us that once they'd been eroded into a cone shape,

  • oriented meteorites had relatively stable trajectories as they traveled through the atmosphere,

  • letting that cone shape remain intact.

  • But that kind of path isn't guaranteed; most of the time, things tend to tumble head over heels.

  • So how did these meteors remain stable as they fell?

  • The authors also found that if an incomingmeteorhas an angle that's too narrow,

  • it bounces around, causing it to break up or erode too unevenly to form a cone.

  • And if the angle is too wide, it'll end up fluttering back and forth like paper falling through the air,

  • which also leads to uneven erosion and no pretty cone.

  • Only if the nose makes an angle of about 60 to 100 degrees

  • will it fly straight the whole way down and become an oriented meteorite.

  • But meteorites aren't just space brought to Earth.

  • They're also pieces of the past that have survived to the present.

  • One group, called the L-chondrites, is particularly intriguing

  • because they all seem to have come from the same parent body at about the same time.

  • And this isn't just a few samples, nearly all known meteorites are classified as chondrites,

  • and up to 40% of those are L-chondrites.

  • Many have been found in southern Sweden, embedded in limestone that's about 470 million years old.

  • One meteorite from this region, though, sticks out like a sore thumb.

  • It's called Österplana 065 and, not only is it not an L-chondrite,

  • it doesn't resemble any other known meteorite.

  • One way to differentiate between meteorites is by looking at the isotopes of the elements it contains.

  • Isotopes are atoms of the same element with a different number of neutrons in their nuclei.

  • The ratio of different isotopes in a substance works kind of like a fingerprint

  • to identify where it might've come from.

  • When scientists examined the oxygen and chromium isotopes from Öst 65,

  • they found ratios very different from the L-chondrites or any other known meteorite.

  • That suggests that Öst 65 comes from a totally different space object than other meteorites we've recovered.

  • So if it's so different, why was Öst 65 found mixed in with a bunch of L-chondrites?

  • Scientists think that if the L-chondrites all came from the same destroyed asteroid,

  • Öst 65 might be a chunk of the object that did the destroying.

  • They collided violently in space only to rest in peace together on Earth.

  • Our final meteorite is unique for both how we found it and what it was hiding inside.

  • It's called Almahata Sitta and it was the first meteorite to be detected before it hit Earth.

  • Astronomers even predicted approximately where it would land,

  • which allowed geologists and volunteers to find and pick up the fragments.

  • And when they cracked open some of the pieces, the scientists found giant diamonds hiding inside.

  • Well, not giant giant diamonds, but bigger than they would have expected.

  • See, diamonds in meteorites aren't actually that surprising.

  • Asteroids often contain carbon,

  • and microscopic diamonds are created all the time as they slam into one another.

  • But a sudden impact can't form a large diamond, for that, you need lots of pressure over long periods of time.

  • Like the conditions you'd find deep inside a planet.

  • Diamonds often contain impurities in the form of minerals trapped inside their structure.

  • Since we know how these minerals form,

  • we can infer what conditions were like where the diamonds were forming.

  • For instance, quartz crystallizes at a relatively low pressure and temperature,

  • while olivine forms only under extreme conditions.

  • This is just because they're made out of different stuff.

  • Sometimes minerals can even take on different structures

  • depending on the conditions of their formation.

  • That's why we have both diamond and graphite, even though both are entirely carbon.

  • Almahata Sitta contains chromite, some phosphate minerals, and some iron-nickel sulfides.

  • Their chemical structures could only form under a pressure of at least 20 gigapascals,

  • which is really high.

  • That tells us that the object they formed inside of was likely at least the size of Mercury,

  • or maybe as big as Mars.

  • Since Mercury and Mars are definitely still around,

  • Almahata Sitta probably came from inside a primordial planet

  • that was destroyed in the chaos of the early solar system, a planet that never quite made it.

  • Which makes this rock from space as old as the Earth itself!

  • So the next time you look up and see a shooting star, just think,

  • Hey, that thing could be chock full of diamonds!”

  • Or maybe not.

  • But either way, it could teach us something we never knew before.

  • Thanks for watching this episode of SciShow Space.

  • Before you go, since you're here and we know you like space,

  • we'd like to draw your attention to September's DFTBA pin of the month,

  • which is this awesome retro take on the Viking lander.

  • This is a pre-order for a pin that will ship in October, and once September ends,

  • they're gone forever, so get them while you can.

  • But don't worry, we'll have another great space pin next month.

  • Check it out at dftba.com or the merch shelf right below this video!

  • [♪ OUTRO]

[♪ INTRO]

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