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  • Hey, Vsauce, Michael here, and I'm sure that we all love to have fun with hand shadows,

  • but how much does a shadow weigh?

  • It might sound like a silly question, because it is. I mean, a shadow cannot be put on a

  • scale and weighed; but, the material that it falls on top of can be weighed. And,

  • we know that light has energy. In fact, when light encounters an object, it pushes that

  • object just a little bit. On the surface of Earth, when sunlight is hitting it, every

  • square inch is being pushed with a force of about one-billionth of a pound, which is basically

  • nothing. But, over a large enough surface area, the results can be pretty fun.

  • On a sunny day, the city of Chicago weighs 300 pounds more, simply because sunlight is

  • falling on it, pushing it.

  • In outer space, where solar wind isn't filtered by Earth's atmosphere or magnetic field, the

  • results are even bigger. A space craft, traveling from Earth to Mars, would be pushed by light

  • 1,000 km off course. So, these things have to be factored into journeys to Mars. We've

  • actually already created things that can sail with light: giant reflective solar sails that

  • are pushed by the Sun's light.

  • So, in a way that is calculable, though difficult to measure, an area covered in shadow technicaly

  • weighs less than surrounding areas being pushed by light.

  • But enough about the Sun. There are 3 astronomical bodies that can cast shadows on the surface

  • of Earth bright enough for us humans to see. One is obviously the Sun, and the other is

  • the Moon. But, what's the third? Venus.

  • Pete Lawrence investigated this over a digital sky. Now, to make sure that the shadow he

  • saw was caused by Venus, he used a tube that could be pointed at specific regions in the

  • sky. Inside the tube, he put a cutout shaped like the astronomical symbol for Venus.

  • Now, here is light coming through the tube when pointed just adjacent to Venus at a point

  • in the sky relatively dark, and empty, to the human eye. But here is what came out of

  • the tube when pointed at Venus: a Venusian shadow.

  • We all know that light travels quickly- 299,792,458 m/s=c.

  • But this light right here, in fact, the light coming off your screen into your eyeballs

  • right now, is moving slightly slower than "c" because "c" is the speed of light in a vacuum,

  • but all of this light if having to travel through a medium- in this case air.

  • The speed of light in air is ever-so slightly slower than "c"- 298,925,574 m/s. This is

  • interesting because light travels more slowly through different materials, but "c" remains

  • the universal speed limit, and as long as an object doesn't go that fast, it can still

  • outpace light in a material.

  • A charged particle- for instance, an electron- can travel through water faster than light

  • does, but never faster than "c". When this happens, we get something analogous to a sonic

  • boom. We get a "Photonic Boom."

  • In a sonic boom, the sound information propagating off of the object is in the form of compression

  • waves, and as the object gets closer and closer to the speed of sound, the speed that those

  • waves are moving away from it at, each new wave has less time to get out of the way of

  • the next until eventually the waves collapse all into each other and the denisty and pressure

  • is enormous, causing a sonic boom.

  • Normally, when a charged particle moves through a material whose molecules can be polarized,

  • the molecules give off photons. But each photon has room to fly away, and the waves all destructively

  • interfere with each other, so no radiation is given off.

  • But, the faster the particle goes, the less room the photons have away from each other,

  • and their waves begin to constructively interfere, giving off a photonic boom: "Cherenkov Radiation."

  • Astronauts, especially those who have gone all-the-way to the Moon, have reported seeing

  • flashes of light. Many people attribute this to high-speed particles moving through the

  • liquid inside their eye faster than light normally would, causing photonic boom's right

  • inside their body.

  • Speaking of the speed of light, here's a great question a few of you have sent me- it involves

  • a possible way of going faster than "c". Here's how it goes:

  • Let's say I want to push a button that is a lightyear away from me, which means that

  • it would take light, the fastest possible thing in the universe, a year just to get

  • from me to the button.

  • Ok, well what if I a built board, one lightyear long, all-the-way from me to the button, and

  • then I pushed one end of the board- would the other end immediately push the button?

  • And, if so, did I just break the speed of light? Did I just send information faster

  • than light? Well, we're not talking about the speed of light anymore, are we? We are

  • talking about the speed of push.

  • When you push a rigid object, what you are really doing is putting a series of compression

  • waves through the object, which move at the speed of sound in the object's material.

  • The information about "whoa, we've been pushed, you should move," is sent via that compression

  • wave, and it only travels at the speed of sound. So, when pushing a normal day-to-day size

  • type object, it feels almost instantaneous. But, pushing a lightyear-long board, it would

  • take a lot longer.

  • A cool way to see this in action is to look at an object in which compression waves travel

  • more slowly. For instance, what Veritasium has done: blowing minds by showing Slinky's

  • being dropped. The information telling the Slinky that "hey, uh, we're moving," travels

  • through the Slinky slow enough that a slow-mo camera can see it happen.

  • If you haven't watched all of Veritasium's Slinky videos, you've missed out. In fact,

  • you should watch all of their stuff, it is superb. But, to wrap things up, here's the

  • point: the speed of push is not instant, and it's certainly not the speed of light. But,

  • light can push you...In fact, technically, you weigh more when the lights are on than

  • you do when the lights are off.

  • I've put links in the description to all kinds of cool things you should definitely check

  • out for fun, and for science. And, as always, thanks for watching.

Hey, Vsauce, Michael here, and I'm sure that we all love to have fun with hand shadows,

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影の重さは? (How Much Does a Shadow Weigh?)

  • 55 4
    Bing-Je に公開 2021 年 01 月 14 日
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