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  • You are a beautiful and unique snowflake. You are NOT a beautiful and unique snowflake.

  • No on else is exactly like you, you're one in a billion. You realize that means there's

  • like eight people exactly like you? Shut up! I am a unique snowflake. That's so cheesy.

  • There's a lot of snowflake science videos out there on YouTube and they all mention

  • the same idea: That no two snowflakes are alike. But where do we get that idea? The

  • universe is a big place, it's really old, and on countless planets with countless snowflakes,

  • surely two of them have been alike.

  • The idea that no two snowflakes are alike probably started on January 15, 1885 in Jericho

  • Vermont. A 20-year-old named Wilson Bentley was sitting outside his farmhouse, freezing

  • his Bentleys off, holding a sheet of black fabric and a turkey feather in the other hand,

  • waiting for a snowflake to fall in just the right spot. And when it did he put that snowflake

  • under a microscope attached to an enormous old camera, and he held his breath, one wrong

  • breath could ruin the whole thing. He opened the shutter and POOF! Wilson Bentley had the

  • first photograph of a snowflake ever taken.

  • Wilson Bentley like SERIOUSLY loved snowflakes, in the sense that he never got married, never

  • moved out of his mom's house, and basically just took pictures of snowflakes for like,

  • 50 years. Now, he called them "masterpieces of design", of course we know there is no

  • design in a snowflake, but that doesn't make them any less amazing.

  • Every plate, every branch, every needle on a needle on a needle, all of those details

  • are what's called emergent properties. This is complexity that's based on very simple

  • rules. For snowflakes, those rules go back to the basic laws of physics.

  • In the air, or in liquid water molecules are zipping around, bouncing off of each other

  • and everything else trillions of times per second, and we have no way of knowing where

  • they are or what direction they are facing at any moment. As we remove heat, it gets

  • colder, and those water molecules start to slow down, eventually their atomic attraction,

  • the actual hydrogen bonds between water molecules, takes over, and they settle into order. That

  • sounds complicated, but we just call that "freezing".

  • The structure of a snowflake can be found in just six water molecules. I know that the

  • angle between any two hydrogens is about 105 degrees, and I know that's true for any water

  • molecule in the universe. For some of those water molecules, the other hydrogen is behind

  • them. Just like that, we've uncovered the six-fold symmetry of a snowflake crystal.

  • That crystal starts as a tiny speck of dust, or pollen, which catches water vapor out of

  • the air and eventually forms the simplest of snowflake shapes: tiny hexagons called

  • diamond dust. Then randomness takes over. There's a very simple reason why a snowflake's

  • arm grows out here and not here. It's just because it sticks out farther and has a higher

  • probability that water molecules will land there. More water molecules and more water

  • molecules land, and then we've got an arm, and another arm, and another arm, and on and

  • on, until we get the intricate and beautiful shapes that we know and love.

  • Depending on temperature and humidity, and a lot of factors that scientists don't even

  • understand, those simple hexagons can give rise to seemingly infinite shapes. Each snowflake

  • will travel through different air currents and bump into different water molecules. BUT

  • . . .

  • In 1998, researcher Nancy Knight claimed to find two identical snowflakes, and they DO

  • look very much alike. It's quite possible that two of those simple hexagons could be

  • the same in every measurement of size and mass, but they would NOT be identical, and

  • physics tells us why.

  • We know that water molecules are made of two hydrogen atoms and an oxygen atom, but not

  • every hydrogen is created equal. If we go back to the Big Bang, we find out that out

  • of every million or so hydrogen atoms created, a couple hundred of them, instead of just

  • being a proton and an electron, are holding on to a neutron. This is the isotope of hydrogen

  • called "deuterium".

  • In Earth's water, even in you, about one in 3,000 molecules will be holding onto deuterium

  • instead of hydrogen. Out of the million million million molecules that make up a snowflake,

  • a lot of them will holding on to deuterium too. Even identical looking snowflakes are

  • not the same.

  • Now you could love a snowflake just because it's pretty, but it doesn't take away from

  • its beauty that it was sculpted by chance and physics. To me, that adds to the beauty.

  • I have to say, this whole "we are unique snowflakes" thing is pretty cheesy. It might be the most

  • overused metaphor in the history of metaphors, so let me give you a new one:

  • Snowflakes are symmetrical, but they're not perfect. They're ordered, but they're created

  • in disorder, every random branch re-tells their history, that singular journey that

  • they took to get here, and most of all they're fleeting and temporary. Even if sometimes

  • they don't look so unique on the outside, if we look within, we can see that they're

  • truly unique after all.

  • Stay curious.

  • [voice over] We're not the only social animals that sit down to eat together, but we are

  • the only ones who cook. Cultural anthropologist Claude Levi-Strauss says that above all, cooking

  • establishes the difference between animals and people

  • We're gonna put a happy little arm over here, look at that happy little snowflake, every

  • one of 'em is unique and beautiful, just like you are.

You are a beautiful and unique snowflake. You are NOT a beautiful and unique snowflake.

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B2 中上級

雪の結晶の科学 (The Science of Snowflakes)

  • 169 26
    Ko Wing Tai に公開 2021 年 01 月 14 日
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