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  • {♫Intro♫}

  • When the Wright Brothers made their first flight in 1903, people had been trying to

  • fly for centuries.

  • So even though their plane didn't go much faster than 10 kilometers per hour -- basically,

  • running speed -- it was a major achievement.

  • What's maybe equally amazing, though, is that it didn't take another few centuries

  • for us to achieve supersonic flight.

  • Chuck Yeager became the first person to fly faster than the speed of sound --

  • more than 1200 kilometers per hour --

  • in 1947, not even 50 years after the Wright Brothers.

  • But making that flight wasn't just a matter of building stronger engines.

  • To do it, engineers had to solve hundreds of problems -- including ditching one of the

  • biggest assumptions in aerodynamics.

  • They clearly did it, though.

  • And today, the innovation that helps keep supersonic planes from falling apart is also

  • the main reason why just about all commercial airplanes look the same.

  • At first, making a faster plane was really just about building better engines and structures.

  • Except, as we got better at flying and started approaching the speed of sound, we noticed

  • that our aircraft

  • just didn't behave like they were supposed to.

  • We first noticed this with propellers.

  • Propellers act like sideways wings, and because they're moving with the plane and spinning,

  • they cut through air a lot faster than the rest of the aircraft.

  • But once propellers got moving faster than about half the speed of sound, they suddenly

  • stopped producing as much thrust as expected. And at high speeds, regular wings also didn't

  • get lift like they did at low speeds.

  • So a plane that flew perfectly at 15% the speed of sound might fall out of the sky at 60%.

  • The problem lingered for about fifteen years,

  • until an aerodynamicist named John Stack found a fundamental flaw in the models and equations

  • everyone used to understand how air moved past objects.

  • In 1933, after looking at experiments in wind tunnels, he realized that air pressure around

  • a quickly-moving object drops, because, ultimately, the air is getting squeezed.

  • That might not seem like a big deal,

  • but it actually violated one of the biggest assumptions in aerodynamics.

  • For decades, people had assumed -- in one form or another --

  • that air is incompressible.

  • It doesn't squeeze or stretch as it runs into things, but instead just glides by or

  • bounces off.

  • In other words, air pressure might change from place to place, but its density doesn't.

  • This assumption means that you don't need to worry about air interacting with itself

  • or how that interaction affects the rest of the world.

  • That makes calculations way easier, and, at slow speeds at least, it's mostly true,

  • Which is why people hadn't had to worry about it.

  • But John Stack and other researchers showed that, as you approach the speed of sound,

  • thinking that air is incompressible is just flat-out wrong.

  • And it has to do with what the speed of sound actually means.

  • Essentially, it's just how fast information -- like that a plane is coming -- can get

  • passed between groups of air molecules.

  • When a plane is going slowly, molecules can push each other out of the way long before

  • the aircraft gets to them.

  • But if the plane is going close to the speed of sound, there's no time for the air to

  • move, so it piles up.

  • That forms a shockwave that acts almost like a shield.

  • It blocks other air from smoothly moving past the plane, decreases lift, and increases drag

  • forces that slow the aircraft down.

  • Which explained why wings and propellers become less effective at those high speeds.

  • After this realization, engineers developed all sorts of clever ways of mitigating this problem,

  • from stabilizers that stopped shockwaves from tearing planes apart to giving planes rocket

  • engines that fought the extra drag.

  • These innovations all culminated in Chuck Yeager's famous flight in 1947.

  • But supersonic or not, shockwaves still threatened to tear planes to pieces.

  • So before high-speed flight became a regular thing, engineers had to make a change to the

  • wings that you can still see on just about any fast plane today.

  • Originally, most planes had wings that went straight out sideways, perpendicular to their bodies.

  • That let air move over as much surface as possible, generating as much lift as possible.

  • The problem was, if a shockwave formed, air didn't have anywhere to go. It just kind

  • of piled up in front of the wing, which led to all those lift and drag issues.

  • So engineers came up with an alternative: swept wings.

  • They're wings that come out of the plane's body at an angle, usually with the wings pointed

  • back toward the tail.

  • The angle meant that air could get pushed along the wings instead of piling up around

  • them -- sort of like sliding down a ramp instead of running into a wall.

  • The fact that swept wings kept air moving more than made up for having slightly less

  • air going across the wings and actually creating lift.

  • And you see this design everywhere today, from military planes to commercial jets, which

  • fly at about 70% the speed of sound.

  • These designs all fundamentally take advantage of the same clever piece of engineering, which

  • is why they all look pretty similar --

  • and why the basic airplane design hasn't changed much in the last 50 years.

  • Because once you've found a solution, you don't always need to keep switching things up.

  • Thanks for watching this episode of SciShow, especially to our patrons on Patreon!

  • Your support has meant a lot over the years, and we're thankful to have been given the

  • chance to make hundreds of these videos.

  • If you want to become a patron and support free science education online, you can go

  • to patreon.com/scishow.

  • {♫Outro♫}

{♫Intro♫}

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