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  • Hey Vsauce! Michael here. Down here.

  • But which way is down?

  • And how much does down weigh? Well, down weighs about a hundredth of a gram per cubic centimeter.

  • It is light and airy which makes it a great source of insulation and buoyancy for water birds

  • but if you let go of down...

  • It falls down.

  • So that's which way down is.

  • It's the direction gravity is pulling everything in.

  • Now, for someone on the other side of the Earth, my down is their up.

  • But where are falling things going? Why do things fall?

  • Are they being pushed, or pulled, or is it because of time travel?

  • First things first: let's turn the Sun into a black hole.

  • We can do that using universe sandbox 2, this simulator will blow your mind. I love it.

  • In fact, I love it so much I put a code to get the game for free in the current curiosity box.

  • If you're not subscribed to the box yet, you are missing out!

  • Okay, look, for the purposes of this video, we want the solar system.

  • And here it is. Notice that everything's moving pretty quickly around the Sun.

  • That's because we currently have the game set so that every second that passes for us,

  • is 14 days, almost, in the game.

  • If I change this to one second,

  • We're looking at the solar system in real time.

  • You'll notice that it almost looks like it's frozen.

  • even though the earth is traveling around the Sun at about 30 km/s, it barely appears to be moving.

  • That is how vast space is. Anyway, let's go back to 14 days

  • I like that motion. Now look at the Sun

  • It is not, currently, a black hole, but we can change that. What we need to do is compress the Sun.

  • So let's lock its mass so that it doesn't change while we make its radius smaller.

  • Let's make its radius as small as we can.

  • And, oh, where'd it go? Well it's still there, it's just become a black hole.

  • Pretty spooky, but now, let's look at the rest of the solar system.

  • Alright, zooming out and-

  • huh.

  • Nothing's... changed. I mean something's changed.

  • It's colder and darker, but nothing's flying off into space or getting sucked in.

  • You see, by shrinking the sun, we didn't change the direction of down for the planets.

  • They're always being pulled by gravity towards its middle and making it smaller didn't move where the middle was.

  • But also, the strength of that force pulling them to the middle of the sun stayed the same.

  • That gives us a clue as to what down is.

  • The clue is the other thing we didn't change: mass.

  • Mass is a measure of how hard it is to accelerate something; to change its motion.

  • Now right now, these two balls have zero motion relative to me.

  • Slapping around this hollow plastic ball

  • is pretty easy, but doing the same to this solid steel ball

  • is a lot harder.

  • Now gravity and weight have nothing to do with this.

  • Gravity acts downward, not against my horizontal slapping.

  • Of course, gravity does contribute to friction, but friction works against me when I start moving the ball,

  • but works with me when I stop the ball.

  • And the steel ball is harder to stop than the plastic ball.

  • The difference is mass. The steel ball is more massive

  • It's more resistant to having its motion changed.

  • Mass is an intrinsic property; it does not depend on what's around or change from place to place.

  • It can sometimes be thought of as the amount of matter something has.

  • Your mass is the same regardless of where you are.

  • On the moon, on earth, in the middle of intergalactic space floating around.

  • But all of this said, mass does seem to care about what's around.

  • Mass loves company.

  • Things with mass and/or energy are attracted together by a force that we call gravity.

  • The feeling of gravity is just you and the earth being attracted to one another.

  • Now every portion of an object with mass attracts other portions towards it.

  • The average of all this pulling is an attraction between centers of mass.

  • Giant things like Earth exert an obvious pull, but everything does. Even a baseball.

  • These two baseballs are attracted together by their own gravities.

  • Except their masses are so small, the force is minuscule, and it can't overcome friction or push air out of the way.

  • They're never gonna come together

  • But if you put two baseballs one meter apart in the middle of empty space where no other forces could act on them

  • They would literally fall together and collide.

  • It would take three days to happen, but it would.

  • Isaac Newton found that the strength of the force bringing two things together is equal to the product of their masses

  • Divided by the distance between their centers of mass squared times big G, the gravitational constant.

  • If you make one of two objects more massive, or move them closer together, the force will be

  • Stronger and this force of attraction is what we call weight

  • So mass is intrinsic whereas weight depends on what's around

  • Now a weird thing happens when you weigh yourself on most scales

  • Weight is a force but scales display pounds or kilograms

  • Which are units of mass what's going on?

  • Is that a scale is

  • activated by a force?

  • Any force.

  • It doesn't have to be caused by gravity. The scale then displays what amount of mass

  • Near the surface of the earth would be attracted to the earth with the force. It's detecting

  • Now since scales tend to be used on the surface of the earth by people on which the only force acting is gravity

  • They tend to not be very far off, but they can be easily tricked and they further lead to the confusion between mass and weight

  • Notice that weight is mutual. You are pulled down by earth with the same force that you pull up on earth.

  • According to a scale I weigh

  • 180 pounds on earth

  • And the earth weighs 180 pounds on me

  • but because the Earth's mass is so much greater than my own and

  • Because the more massive something is the more it resists being moved our

  • Equal and opposite weight forces accelerate me a lot more than the earth

  • If you drop a pencil from a height of 6 feet the pencil doesn't just fall to the earth more precisely

  • They both come together.

  • They're attracted to each other by equal forces

  • but the same force moves the pencil a

  • Lot more than the earth when you let go of the pencil the earth is literally pulled up

  • To the pencil by the pencils own gravity a distance equal to about 9 trillion

  • the width of a proton. That

  • same force moves the pencil the remaining distance, which is still pretty much six feet

  • At the height of the International Space Station's orbit you and earth are attracted about

  • 10% less than when you're on the surface about eight point eight times your mass but not zero

  • for this reason weightless astronauts in zero gravity are neither weightless nor in zero gravity

  • their weight force fails to bring them and earth together because they move horizontally

  • So quickly that they fall. Just as fast as Earth's surface curves away from them and

  • Even though they're experiencing 90 percent of the gravity you and I are feeling right now

  • That's why they don't just fly away

  • There are no forces called g-forces to resist their weight since everything around them is falling too

  • It's resistance to your weight force stress

  • Deformation that is needed for you to feel weight what astronauts in orbit actually lack is

  • apparent weight

  • likewise a helium balloon has weight

  • I mean, it's made out of matter it clearly has mass so it's attracted to the earth

  • Let's try to measure its weight force

  • That's eight

  • Okay it has negative apparent weight

  • That's because its attraction to the earth is weaker than the buoyant forces from the air around it that push it up

  • Now while it moves up

  • It pushes air molecules down, but they transfer that force widely. Not just directly down onto the scale

  • Buoyant forces are caused by the fact that whenever you are immersed in a fluid like water or air

  • Molecules lower down are at greater pressure

  • That are being pressed by the weight of all the molecules

  • Above them and are closer to earth so they're pulled to it with a stronger force now having greater pressure

  • Means they pack a bigger punch when they collide with things.

  • So

  • horizontally those collisions cancel out

  • But vertically the stronger collisions from below went out providing lift a buoyant force

  • This even happens on your own body across its surface area air lifts you with the force of about one

  • Newton which is equal to the weight force of an apple so if you weighed yourself in a vacuum you would weigh about

  • this much more

  • But that's not all Earth's spin causes it to bulge at the equator so the closer you are to it

  • The further you are from Earth's center of mass and the less your actual gravitational weight will be down is

  • Always changing, I mean

  • where is Earth's center of mass? It would always be the same as Earth's geometric middle if Earth's

  • composition was uniform, but earth contains pockets of massive rock at different depths water mountains

  • It's got moving changing insides and air and seasonal ice and though they're far away

  • Gravity extends forever from everything so the moon the Sun the planets all of them pull on you

  • negligibly,

  • But truly. You weigh about a millionth of your weight less when the moon is directly above you

  • This chunky shifting balance of material on earth and ever where else in the universe means that down is

  • always

  • changing on top of that Earth's spin

  • Skews what you consider the direction of down away from its center of mass because the push you get from Earth's spin

  • Seems to slightly lift you reducing your apparent weight and bending down

  • towards the equator

  • The net result is an apparent weight reduction at the equator of about half of a percent if a scale guesses your mass must be

  • 200 pounds at the poles it'll guess that you're

  • 199 at the equator. The 9.8

  • Multiplier used so often in physics is calculated based on how these factors affect someone at 45 degrees latitude

  • all of these influences on the direction of down result in a total vertical deflection.

  • That's only ever at most a few arc seconds anywhere on earth

  • That's not enough to be felt, but changes in direction and strength can be used to study the shape of the seafloor

  • Determine what's under you or even help you discover ancient buried rooms?

  • Point is all of our downs aren't a bunch of radially symmetric lines

  • Down is an uncombed mess.

  • Now since solids don't flow they can have shapes that don't pay much mind to this but water can

  • Flow so ignoring influences like wind and tides the surface of oceans and lakes and puddles is always perpendicular

  • To down if water could pass through land, or if earth were submerged in water

  • Gravity would be the same everywhere along its bumpy surface

  • Such a surface is called a geoid and can be drawn at any altitude

  • If you wanted to build a table that completely enclosed the earth it would have to have rolling undulation

  • Z' nearly 100 meters at some points in order to be

  • Level so that a ball placed anywhere on it wouldn't roll

  • Here is Earth's G. I exaggerated a thousand times

  • You'd weigh about a hundredth of a percent less a few grams here?

  • Then you would say here where gravity is a bit stronger point is the strength and direction

  • Down is variable by location and changes over time

  • So down is a fluctuating vector easy enough except?

  • Why should matter attract matter in the first place?

  • Isaac Newton was able to describe attraction, but not explain it

  • humanity got closer however when Albert Einstein introduced his general theory of relativity

  • Einstein thought a lot about the fact that everything falls to the ground

  • At the same rate no matter

  • How massive something is when dropped it will accelerate towards the earth down gaining about 9.8

  • Meters per second for every second that it falls. That means that a hammer

  • That's quite massive, and a not so massive feather when dropped from the same height will hit the ground at the same time

  • Okay, what just happened...

  • was an "air"ror.

  • awkward laugh

  • In order to fall through air a thing has to push air out of the way

  • But if it has a large surface area and a low weight force it will have a lot of air to move

  • But won't be able to move that air very quickly. In a vacuum, things do fall at the same rate regardless

  • Of mass. This was famously demonstrated by Apollo 15 commander David Scott on the moon

  • And I'll, uh, drop the two of them here and hopefully, they'll hit the ground at the same time.

  • How 'bout that?

  • That's weird right? I mean if a more massive object is pulled with a greater force

  • Shouldn't it fall faster? Well Newton's explanation was simple:

  • Larger masses are attracted with greater forces

  • But will also require more force to be accelerated the same as a less massive thing

  • Something a hundred times more massive might require a hundred times the force, but it will be pulled by gravity

  • 100 times more so everything falls to earth at the same rate

  • What a fun coincidence right?

  • Maybe not

  • Einstein realized that there's another way for things to appear to fall together

  • of their masses

  • Imagine a feather and a hammer floating in space in a room if the room is suddenly accelerated up at 9.8

  • M/s^2 the feather and the hammer will hit the floor at the same time

  • furthermore whether it's the room coming up to meet them or gravity being suddenly switched on

  • Neither object will feel any force pushing them

  • There's no way to tell which of these happen. This is Einstein's famous

  • equivalence principle

  • He once admitted that his greatest thought ever was that of a man

  • falling off of a roof

  • While falling the man would not feel any forces on him even though. He's speeding up

  • freefall is

  • Indistinguishable from floating alone in space from having no forces on you from not being moved

  • What if gravity isn't a force at all what if things fall not because they're being pushed or pulled

  • But because they're not being pushed or pull

  • To see how this could be we need to talk about straight lines

  • What I have here is a retractable ID badge holder

  • This is a great way to test for straight paths

  • Because the string is always kept taut the card

  • I have behind has two lines drawn on it

  • And if while I pull the string out it always stays between those two lines

  • I will know that I never turned

  • While I pulled it because any turn will translate into a different angle between the lines on the card and the string

  • Now if I put two of these on a flat table and pull them out, always ensuring that they go straight ahead

  • They will never meet. They will be forever parallel, but now let's put them on a sphere a curved surface

  • Again, I pull both strings forward making sure that they always are pulled out straight. No turning

  • Wait they came together

  • Well, they didn't turn look

  • Maybe there's some kind of weird force that pulled my hands together and just like gravity. I didn't feel it, but it happened

  • No

  • What happened was not the result of a force it was just a natural result of?

  • Curvature you might be thinking wait a second are those really straight lines. I mean they don't look that straight to me

  • Also, what if they've just moved along latitude lines then they've never come together and those look pretty darn straight

  • But they're not a straight line never turns and although latitude lines look straight at first glance

  • following one requires

  • Turning to find straight line paths on surfaces whether they're flat like this or curved

  • I love the written text now you can use an actual ribbon

  • But I have found that a strip of paper works. Even better. Let's take a look at this path right here

  • It's straight at first, but then it curves now if two people are traveling along this curve

  • And they want to stay together the person on the inside will have to cover a shorter distance than the person on the outside

  • Since both sides of this strip of paper cannot change their lengths

  • They'll help us find a straight path if the strip of paper can lay flat

  • We'll know that we have found a straight line and as you can see

  • The strip can lay flat and follow the straight part of this path

  • But when it comes to the curve in order to follow the path now

  • The strip well it has too much material on the inside and that material

  • Bunches up and leaves the plane therefore we know that this part of the path is not straight

  • Let's use the ribbon test to find straight lines on the surface of a cone

  • Well from the looks of it aligned directly from the base to the tip seems like it would be straight and sure enough

  • Yeah, the ribbon lays flat on that path, but what about a ring around the cone?

  • Nope doesn't work shorter distances around nearer the tip of the cone mean that there's too much ribbon up at the top

  • So doesn't lay flat

  • Let's see what else is there though besides this well if I start here and just allow the ribbon

  • to lay flat

  • Huh I get a little curvy looking shape like this

  • I say curvy looking because while to someone say at the base this path might seem to go up

  • Slow down change direction and then fall down faster and faster since a ribbon on such a path is flat

  • It's actually for inhabitants on the cones surface

  • Perfectly straight if we trace the ribbons path on to the cone

  • We can see this clearly because a cone can be flattened a straight line on a curved surface is called a geodesic

  • Here is a geodesic on a sphere the Equator is one

  • Here's another a line of latitude is not a geodesic

  • It's not a straight line to see why let's try to follow it with the ribbon you

  • Know what I have to keep kind of lifting it

  • Yeah, see distances around the sphere becomes shorter as we go up

  • So there's too much material on the ribbon up here

  • and it leaves the surface this path contains turns and in order to turn a

  • Force has to act on you if no forces

  • Did this is the path you would take notice that the ribbon begins moving due east, but then falls

  • south

  • Falls

  • Einstein realized that curvature could cause things to be seemingly attracted to one another

  • Without needing to invent the existence of forces like gravity

  • but attraction only happens if things move along the surface if they stay still they

  • Well, they don't come together so for something at rest. How does falling begin?

  • I mean the thing has to move in this direction, but it's at rest right well

  • Yes

  • But it's only at rest in space and that's not the whole story up down

  • Forward backward and left-right are all you need to describe where an event occur but a complete description will also need to describe

  • When together these four dimensions form the setting in which everything in our universe happens

  • Space-time

  • Since we can talk about a falling pencil using just one spatial dimension up and down we can use a piece of paper to model

  • Space-time for it. Okay, so we've got up and down, but we have to add another

  • direction the pencil moves in

  • time

  • Now if no forces act on the pencil it won't move through space

  • It will only get older and as you can see if all it does is get older

  • It won't fall if space-time was flat when I let go of the pencil

  • it wouldn't go anywhere, but now let's allow the earth which is massive to manipulate space-time into say a

  • cone

  • Now with no forces acting on it every part of the pencil follows a straight line

  • But on a cone as we saw earlier such a path will look like this it will fall

  • This is because distances around the cone are shorter higher up

  • Time runs faster further from a massive object, but to go straight

  • Not turn every part of the pencil must cover an equal distance in space-time

  • like this

  • Only when the pencil hits the earth does the repulsion of their mutual electrons provide a force pushing the pencil off a geodesic

  • For the earth time is a series of slices from this evolution the pencils force-free

  • Geodesic is why it falls not a push or pull just the pencils natural tendency to follow a straight line

  • Until something acts on it now. We only used one dimension of space and one of time because

  • Visualizing our universes three of space and one of time would take us beyond the limits of what could be shown on paper or screens

  • but math

  • Can take us there

  • General relativity allows us to calculate how much mass and energy

  • Curved space-time and has been used to explain things that Newton's older theory of falling as the result of

  • Forces couldn't like anomalies in the orbit of mercury which orbits nearest the Sun and is therefore most affected by the sun's grip on

  • space-time many other experiments have confirmed general relativity's picture of the universe fitting the conclusion that

  • There is no

  • Gravity there's just

  • Space-time its curvature and a us in it. As John Wheeler famously put it

  • Space-time grips mass telling it how to move mass grips space-time telling it how to curve?

  • Relative to the earth we don't move very fast even jet airplanes move negligibly close to the speed of light

  • So relative to earth we move almost

  • Exclusively through time as such we are more affected by the way time is curved by mass

  • Than how space is curved?

  • This has led many to claim that for the most part you feel as though you're being pushed into the ground

  • Not because of a force called gravity

  • But because time is moving faster for your head than for your feet down is

  • Relative and always changing, but it exists because of and is always in the direction of slower time

  • Bertrand Russell called this the law of cosmic laziness

  • Everything is naturally steered towards where time is slowest we call this falling

  • going down

  • So you don't have to keep anything on the down-low

  • time will take care of that for you and

  • and as always

  • Thanks for watching

  • Remember that you can support Vsauce and Alzheimer's research by subscribing to the Vsauce

  • curiosity box the current one comes with a code to get a free copy of universe sandbox 2

  • Which is amazing and a whole host of other science toys and tools picked by myself Jake and Kevin

  • I love it all so I hope to see you at brain candy live. We are coming to many many cities very soon

  • Hopefully one near you by going to the show you can see Adam

  • And I doing things that will you may not have seen us do before we also explore the science and common

  • misconceptions behind all things

  • Err. Maybe have said too much. Maybe not I hope to see you there and as always thanks for watching

Hey Vsauce! Michael here. Down here.

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どっちが下? (Which Way Is Down?)

  • 55 1
    Samuel に公開 2021 年 01 月 14 日
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