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  • - I'm guessing that you've had the experience of rubbing

  • a balloon against your hair and then when you take

  • the balloon away from your hair, your hair sticks up.

  • And if you haven't had that experience,

  • you might think about trying to lead

  • a more rich and fun life,

  • but I'm guessing most of you all have done that.

  • And you had a sense that it had something to do with the

  • balloon or your hair, somehow exchanging charge or now

  • one is going to be more positive or negative than the other,

  • and so now they are somehow attracted.

  • And if you were thinking of those things,

  • you are generally right.

  • What you just experienced after you rubbed the balloon

  • on your head, and then your hair is now attracted

  • to the balloon, that's actually called

  • the triboelectric effect, let me write that down,

  • tribo, triboelectric, electric effect.

  • And human beings have been observing this

  • for a long long time, and it wasn't necessarily

  • with balloons at birthday parties or whatever,

  • it's with other things, they rub a silk cloth on a piece

  • of glass and then they'll see that there's some type

  • of attraction, or they might see that if they

  • do that enough, one of the objects might discharge

  • when it touches another object.

  • People have observed things like lightning,

  • where it looks like there's some type of a buildup

  • and some type of a potential and then all of a sudden

  • it discharges and you have this lightning and then this

  • thunder blast sound that happens too.

  • So this is something that humans have observed

  • for a long long time, and scientists or people with a,

  • I guess you could say a scientific mind have been trying

  • to understand it for a long long time, and trying to come up

  • with a framework for what exactly is happening.

  • Well lucky for us, we now have a framework for it

  • that explains it quite well.

  • And that framework for what is going on

  • with that triboelectric effect,

  • is a framework around charge.

  • Is a framework that we now have around charge.

  • And this tells us, this way of looking at the world,

  • says look, there's some things

  • that just have a property called charge.

  • Some things have a positive charge,

  • Some things have a positive charge, and it's somewhat

  • of an arbitrary name, we just happen to call it positive.

  • And some things have what we say is an opposite charge,

  • or a negative charge, a negative charge.

  • We could have called this the magenta charge,

  • and this the green charge, we could have called this

  • the hippopotamus charge and this the ostrich charge.

  • And we could have said that hippopotami, I believe plural

  • for hippopotamus, they're always attracted to ostriches,

  • but they always repel other hippopotami, and likewise.

  • The like charges repel or like hippo...

  • You get the general idea.

  • But I'll stick to the words that people are used to using.

  • And so if we say something has a charge,

  • say a positive charge,

  • and something else has a negative charge,

  • then in our framework that we're setting up,

  • these two things are going to attract.

  • So opposite charges are going to attract,

  • while like charges are going to repel.

  • So if you have a positive charge,

  • and you have a positive charge,

  • these things are going to accelerate,

  • are going to accelerate away from each other.

  • And that's not just true for positive positive,

  • that's also true for negative and negative,

  • these two things are going to repel

  • because they are like charges.

  • Now it's very interesting to think about this

  • because we are so used to thinking in terms of charge,

  • even you know if, especially in kind of the world

  • of electricity you have the positive and negative terminal.

  • You think of charging up your phone or whatever else.

  • That it seems like, we completely, charge is just something

  • that is fundamental about the universe,

  • and that's true to some, that's true,

  • but you'd have to appreciate that these are arbitrary words

  • and they're really just to describe a property

  • that we have observed in the world.

  • And if you go down to the atomic level, we can get to

  • a fundamental level of where the charge is happening.

  • But once again, these are really models

  • for our brain to describe, these are frameworks and models

  • for our brain to be able to predict and describe

  • what we observe in the world.

  • But if we run with this model,

  • we can imagine at the atomic scale,

  • the nuclei of atoms are composed of protons and neutrons.

  • So if you have some protons, and then you have

  • some neutrons, I'll do two of each, you have some neutrons,

  • and based on this framework, protons have a positive charge.

  • Protons have a positive charge.

  • Now once again, this convention of calling them positive

  • and putting a plus on it, it's not like protons have

  • a little plus sign tattooed onto them somehow.

  • We could have called those, we could have said

  • they have a red charge, or we could have even said,

  • we wouldn't of had to even use the word charge,

  • this is just a convention that we have decided to use.

  • And so we say protons have positive charge and then,

  • kind of buzzing around the nucleus of an atom, you often,

  • or usually, or often have electrons.

  • Electrons have a lot less mass.

  • Mass is another interesting thing.

  • We associate mass as just, oh this is just something

  • that we get, we understand it in our everyday life,

  • but even mass, this is just a property of objects,

  • it's just a property of matter,

  • and we feel like we understand it because on our scales

  • we understand notions of things like weight and volume,

  • but even mass can get quite exotic.

  • But anyway, the whole point of this video is

  • not to talk about mass, it's to talk about charge.

  • But all of these things that we talk about in physics,

  • these are just properties that will help us deal

  • with these notions, these behaviors in different frameworks.

  • But anyway, let's get back to this little atom

  • that I was constructing.

  • So this atom, let's say it has two electrons,

  • and obviously this is not drawn to scale,

  • and each of these electrons have a negative charge,

  • and they're kind of jumping around here,

  • buzzing around this nucleus of this atom.

  • And the reason why, this model, even going down

  • to the atomic scale and thinking in protons and electrons

  • is interesting, is that it allows us to start explaining

  • what is happening in the triboelectric effect.

  • What is happening in the triboelectric effect is when you

  • rub that balloon on your hair, because of the property

  • of the balloon, the material of the balloon,

  • and the materials of your hair,

  • when they come in contact and they rub,

  • the balloon is grabbing electrons from your hair.

  • So the balloon is grabbing electrons from your hair,

  • and so it is getting more negatively charged,

  • it is getting more negatively charged,

  • and your hair is getting more positively charged,

  • or essentially it's lost these electrons.

  • And so when you put the balloon now close to your hair,

  • remember like charges repel each other,

  • so the electrons in your hair try to move away

  • from these other electrons, the negative charge tries to

  • move away from the negative charge,

  • and I guess you could say that

  • the tips of your hair will then become more positive.

  • Are more positive and they will be attracted,

  • and they will be attracted to the balloon.

  • So we can think about what's happening in terms

  • of transfer of electrons, that's exactly what's happening.

  • And so when you think that way, it's like ok,

  • we are scientists, this is a nice model,

  • we can start to think about what's happening here.

  • This model actually explains a whole ton of behavior

  • that we've observed in the universe, including things like,

  • lightning and whatever else, you know the static shock

  • that you get when you might touch a doorknob

  • after rubbing your shoes along the carpet.

  • But we like to start, we like to quantify things,

  • so we can start seeing how much they repel

  • or how much they attract each other.

  • And so the fundamental unit of charge,

  • or one of the fundamental units of charge,

  • or I guess you could say the elementary unit of charge

  • is defined in terms of the charge

  • of a proton or an electron.

  • So the fundamental, or I guess you could say the

  • elementary unit of charge is denoted by the letter e,

  • and this is the charge of a proton,

  • this is e for elementary, charge of proton.

  • And the charge of an electron, even though an electron has a

  • much, much, much, much smaller mass than a proton,

  • most of the mass of an atom is

  • from the protons and the neutrons.

  • So an electron has a much, much smaller mass

  • than the protons and the neutrons,

  • but it has the same but opposite charge as a proton.

  • So sometimes the convention is to write negative e,

  • or maybe even negative one e, sometimes depending on

  • whether you view this as a kind of the actual charge

  • or whether you view this as a unit,

  • but here I'll view this as the actual charge.

  • You could view negative e as the charge,

  • as the charge of an electron.

  • And something that has no charge,

  • like a neutron, we say they're neutral,

  • and actually that is why they are called neutrons,

  • because they are neutral, they don't have charge.

  • So that right over there, that over there is, is a neutron.

  • Now when we start to get on kind of a larger scale,

  • not on a sub-atomic scale anymore,

  • talking about electrons and protons, the unit of charge,

  • in general the unit of charge that we typically use

  • is the coulomb, is the coulomb.

  • Coulomb, it's named for Charles Augustin de Coulomb,

  • so if we're talking about the guy, and he was

  • an 18th Century French physicist, we would use capital C,

  • but if we're talking about the units,

  • we would use lowercase c, the coulomb, the coulomb.

  • And the coulomb is defined, so one coulomb,

  • let me write it right over here, one coulomb

  • and it uses the abbreviation uppercase C, is equal,

  • or I'll say approximately equal to,

  • we're going to round here, it's approximately equal to

  • 6.24, 6.24 times 10 to the eighteenth e, or you could say,

  • in magnitude wise, it's equal to the charge

  • of 6.24 times 10 to the eighteenth protons,

  • or magnitude wise,

  • it would be the opposite if you're talking about electrons,

  • it would be 6.24 times 10 to the eighteenth electrons.

  • Now if you want to go the other way around,

  • what is the charge of, the magnitude of the charge

  • of say a proton in terms of coulombs,

  • well you would just take the inverse of this.

  • So you could say that e is approximately equal to

  • the inverse of this which is 1.60,

  • I guess you could say the reciprocal of this,

  • 1.60 times 10 to the negative 19,

  • times 10 to the negative 19 coulombs.

  • So hopefully this gives you an appreciation for,

  • I guess at a base level, what charge is.

  • And in some ways it's like it's this everyday thing,

  • you're used to it, we're used to dealing with electricity

  • and we'll talk much more about that in depth.

  • But at some levels it is this thing,

  • one of the mysteries of the universe,

  • how did these two particles know to attract each other,

  • you know it looks like they're at a distance,

  • how do they immediately exert a force on each other.

  • how do these particles know immediately to repel each other,

  • it's not like they have a wire connecting them

  • that they're communicating somehow,

  • or I guess once you get to quantum mechanical,

  • an argument can be made that they are communicating somehow.

  • But in our everyday, kind of logical sense,

  • it's like well at a distance,

  • how do these things actually know to repel or attract,

  • and what is this charge anyway?

  • You know we've put all these names around it

  • but to kind of help us think about it and have a framework

  • and predict what will happen.

  • But do we really know what this charge thing is.

  • So on one level it's kind of plain and mundane,

  • and it deals with balloons and hair,

  • but on another level it's this deep thing

  • about this universe, it's a deep property of matter

  • that we can manipulate and we can predict, but it is still

  • this very fundamental and somewhat mysterious thing.

- I'm guessing that you've had the experience of rubbing

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Triboelectric effect and charge | Physics | Khan Academy

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    yukang920108 に公開 2022 年 07 月 19 日
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