The sonic boom problem - Katerina Kaouri

5,017,397 views ・ 2015-02-10

TED-Ed


Please double-click on the English subtitles below to play the video.

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Humans have been fascinated with speed for ages.
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The history of human progress is one of ever-increasing velocity,
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and one of the most important achievements in this historical race
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was the breaking of the sound barrier.
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Not long after the first successful airplane flights,
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pilots were eager to push their planes to go faster and faster.
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But as they did so, increased turbulence
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and large forces on the plane prevented them from accelerating further.
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Some tried to circumvent the problem through risky dives,
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often with tragic results.
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Finally, in 1947, design improvements,
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such as a movable horizontal stabilizer, the all-moving tail,
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allowed an American military pilot named Chuck Yeager
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to fly the Bell X-1 aircraft at 1127 km/h,
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becoming the first person to break the sound barrier
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and travel faster than the speed of sound.
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The Bell X-1 was the first of many supersonic aircraft to follow,
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with later designs reaching speeds over Mach 3.
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Aircraft traveling at supersonic speed create a shock wave
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with a thunder-like noise known as a sonic boom,
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which can cause distress to people and animals below
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or even damage buildings.
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For this reason,
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scientists around the world have been looking at sonic booms,
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trying to predict their path in the atmosphere,
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where they will land, and how loud they will be.
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To better understand how scientists study sonic booms,
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let's start with some basics of sound.
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Imagine throwing a small stone in a still pond.
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What do you see?
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The stone causes waves to travel in the water
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at the same speed in every direction.
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These circles that keep growing in radius are called wave fronts.
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Similarly, even though we cannot see it,
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a stationary sound source, like a home stereo,
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creates sound waves traveling outward.
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The speed of the waves depends on factors
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like the altitude and temperature of the air they move through.
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At sea level, sound travels at about 1225 km/h.
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But instead of circles on a two-dimensional surface,
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the wave fronts are now concentric spheres,
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with the sound traveling along rays perpendicular to these waves.
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Now imagine a moving sound source, such as a train whistle.
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As the source keeps moving in a certain direction,
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the successive waves in front of it will become bunched closer together.
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This greater wave frequency is the cause of the famous Doppler effect,
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where approaching objects sound higher pitched.
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But as long as the source is moving slower than the sound waves themselves,
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they will remain nested within each other.
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It's when an object goes supersonic, moving faster than the sound it makes,
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that the picture changes dramatically.
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As it overtakes sound waves it has emitted,
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while generating new ones from its current position,
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the waves are forced together, forming a Mach cone.
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No sound is heard as it approaches an observer
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because the object is traveling faster than the sound it produces.
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Only after the object has passed will the observer hear the sonic boom.
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Where the Mach cone meets the ground, it forms a hyperbola,
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leaving a trail known as the boom carpet as it travels forward.
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This makes it possible to determine the area affected by a sonic boom.
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What about figuring out how strong a sonic boom will be?
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This involves solving the famous Navier-Stokes equations
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to find the variation of pressure in the air
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due to the supersonic aircraft flying through it.
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This results in the pressure signature known as the N-wave.
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What does this shape mean?
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Well, the sonic boom occurs when there is a sudden change in pressure,
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and the N-wave involves two booms:
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one for the initial pressure rise at the aircraft's nose,
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and another for when the tail passes,
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and the pressure suddenly returns to normal.
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This causes a double boom,
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but it is usually heard as a single boom by human ears.
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In practice, computer models using these principles
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can often predict the location and intensity of sonic booms
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for given atmospheric conditions and flight trajectories,
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and there is ongoing research to mitigate their effects.
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In the meantime, supersonic flight over land remains prohibited.
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So, are sonic booms a recent creation?
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Not exactly.
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While we try to find ways to silence them,
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a few other animals have been using sonic booms to their advantage.
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The gigantic Diplodocus may have been capable of cracking its tail
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faster than sound, at over 1200 km/h, possibly to deter predators.
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Some types of shrimp can also create a similar shock wave underwater,
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stunning or even killing pray at a distance
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with just a snap of their oversized claw.
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So while we humans have made great progress
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in our relentless pursuit of speed,
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it turns out that nature was there first.
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