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  • [♪ INTRO]

  • In nature, most of our basic forces both attract and repel.

  • In fact, gravity is the only exception.

  • As far as we can tell, anything gravity acts on just goes one way: down.

  • As long as there's no other forces involved, anyway.

  • But there is actually an exception to the exception.

  • On a teeny-tiny scale, we're exposed to negative gravity every day.

  • Because, according to theorists, sound waves, of all things, have negative gravity.

  • And what's even more amazing is that you don't need fancy science

  • like quantum mechanics or general relativity to understand why.

  • You can understand real-life negative gravity using classical physics;

  • the stuff you probably learned in high school.

  • Now, I know the idea that gravity acts on sound at all might seem a little sketchy,

  • because sound waves aren't some special kind of matter.

  • They're just vibrations:

  • the scrunching up and stretching out of molecules like those in the air.

  • Still, scientists argue that you can think of them as particles.

  • Kind of like you can think of light as particles, or photons.

  • In sound, though, they're called phonons.

  • Phonons aren't like electrons or molecules or any other particles you're familiar with.

  • They're essentially packets of energy moving at a similar speed.

  • As a sound wave passes through the air,

  • molecules speed up as they squish together and slow down as they spread out.

  • And a phonon is a tiny packet of those vibrations.

  • So it's not exactly a single physical particle.

  • It's more like a flock of birds.

  • A flock is just a bunch of individual birds, but you can still identify it as its own unit.

  • And that's the idea with phonons as well.

  • It's like a “flockof vibrations that emerge from a sound wave.

  • The weird thing about these phonons is, according to theory,

  • they move upward in a gravitational field.

  • It might seem like that just shouldn't happen; that's not how gravity works.

  • But the reason is actually pretty straightforward.

  • Picture a sound wave moving through the air.

  • Air pressure is slightly greater at the bottom of that wave than at the top,

  • because the lower air is denser.

  • It's just like how water pressure is greater near the ocean floor than it is near the surface.

  • Since sound vibrations travel faster through denser fluids,

  • the bottom of the sound wave, where the air is under a lot more pressure, travels faster.

  • And that makes the whole thing bend up. Just ever-so-slightly.

  • That means the sound wave, and the phonons that make it up, are going against gravity.

  • In other words, phonons have negative mass.

  • Because anything with a positive mass would get pulled down.

  • This is an actual, physical effect, not just an illusion.

  • It's not like an airplane taking off, or a bird flying, either.

  • Gravity is still pulling down on those things, even as they move up.

  • But sound waves are actually falling up.

  • And that comes with some pretty wild consequences.

  • The first thing is, over large enough distances, all sound waves should curve upward.

  • This probably wouldn't have any real-world impacts,

  • like, it's not going to change how we communicate.

  • The amount of predicted curving is so small

  • that we don't even have instruments sensitive enough to detect it.

  • But scientists think this effect could be more relevant in objects like neutron stars,

  • where sound waves travel through super-dense fluids.

  • There, phonons could significantly affect the star's behavior.

  • But that's not the end of the story, either.

  • Because on top of defying gravity themselves,

  • sound waves should also push away anything with mass.

  • See, anything with mass has gravity.

  • And not just big things, like, you have your own gravitational field.

  • And so do phonons.

  • Except, since phonons have negative mass, they also have negative gravity.

  • Meaning they should repel anything with mass.

  • Again, we don't have the technology to measure this kind of effect yet,

  • since gravity is pretty weak on a microscopic level.

  • But this is still fascinating.

  • And this weird behavior is all based on pretty simple, old-school physics;

  • stuff that's been sitting right in front of us for literally hundreds of years.

  • So, what do you know? It turns out, now and then, old physics can do new tricks.

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  • To find out more, head over to Brilliant.org/SciShow.

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  • And as always, thanks for watching SciShow.

  • [♪ OUTRO]

Thanks to Brilliant for supporting this episode of SciShow.

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