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  • - [Instructor] Let's try a hard one.

  • This one's a classic.

  • Let's say you have two charges,

  • positive eight nanoCoulombs and negative eight nanoCoulombs,

  • and instead of asking what's the electric field

  • somewhere in between, which is essentially

  • a one-dimensional problem, we're gonna ask,

  • what's the electric field up here, at this point, P?

  • Now, this is a two-dimensional problem

  • because if we wanna find the net electric field

  • up here, the magnitude n direction

  • of the net electric field at this point,

  • we approach it the same way initially.

  • We say alright, each charge is gonna create a field

  • up here that goes in a certain direction.

  • This positive charge creates a field

  • up here that goes radially away from it,

  • and radially away from this positive

  • at point P is something like this.

  • I'll call this electric field blue E

  • because it's created by this blue positive charge,

  • and this negative charge creates its own electric field

  • at that point that goes radially into the negative,

  • and radially into the negative

  • is gonna look something like this.

  • I'll call this electric field yellow E

  • because it's created by the yellow electric field.

  • So far so good.

  • Same approach, but now things get a little weird.

  • Look, these fields aren't even pointing

  • in the same direction.

  • They're lying in this two-dimensional plane,

  • and we wanna find the net electric field.

  • So what we have to do in these 2D electric field problems

  • is break up the electric fields into their components.

  • In other words, the field created by this positive charge

  • is gonna have a horizontal component,

  • and that's gonna point to the right.

  • And I'll call that blue E x because it was the horizontal

  • component created by the blue, positive charge.

  • And this electric field is gonna have a vertical

  • component, that's gonna point upward.

  • I'll call that blue E y.

  • And similarly, for the electric field this negative charge

  • creates, it has a horizontal component

  • that points to the right.

  • We'll call that yellow E x, and a vertical component,

  • but this vertical component points downward.

  • I'll call that yellow E y.

  • What do we do with all these components

  • to find the net electric field?

  • Typically what you do in these 2D electric problems

  • is focus on finding the components

  • of the net electric field in each direction separately.

  • We divide and conquer.

  • We're gonna ask, what's the horizontal component

  • of the net electric field, and what's

  • the vertical component of the net electric field?

  • And then once we know these, we can combine them

  • using the Pythagorean theorem if we want to,

  • to get the magnitude of that net electric field.

  • But we're kind of in luck in this problem.

  • There's a certain amount of symmetry

  • in this problem, and when there's a certain amount

  • of symmetry, you can save a lot of time.

  • What I mean by that is that both

  • of these charges have the same magnitude of charge.

  • And because this point, P, lies directly

  • in the middle of them, the distance

  • from the charge to point P is gonna be the same

  • as the distance from the negative charge to point P,

  • so both of these charges create an electric field

  • at this point of equal magnitude.

  • The fields just point in different directions,

  • and what that means is that this positive charge

  • will create an electric field that has

  • some vertical component upward of some positive amount.

  • We don't know exactly how much that is,

  • but it'll be a positive number because it points up,

  • and this negative charge is gonna create

  • an electric field that has a vertical component downward,

  • which is gonna be negative, but it's gonna have

  • the same magnitude as the vertical component

  • of the blue electric field.

  • In other words, the field created by the positive charge

  • is just as upward as the field created

  • by the negative charge is downward.

  • So when you add those up, when you add

  • up these two vertical components to find the vertical

  • component of the net electric field,

  • you're just gonna get zero.

  • They're gonna cancel completely,

  • which is nice because that means we only have

  • to worry about the horizontal components.

  • These will not cancel.

  • How come these don't cancel?

  • Because they're both pointing to the right.

  • If one was pointing right and the other was left,

  • then the horizontal components would cancel,

  • but that's not what happens here.

  • These components combine to form a total component

  • in the x direction that's larger than either one of them.

  • In fact, it's gonna be twice as big

  • because each charge creates the same amount

  • of electric field in this x direction

  • because of the symmetry of this problem.

  • So we've reduced this problem to just finding

  • the horizontal component of the net electric field.

  • To do that, we need the horizontal components

  • of each of these individual electric fields.

  • If I can find the horizontal component

  • of the field created by the positive charge,

  • that's gonna be a positive contribution

  • to the total electric field, since this points

  • to the right, and I'd add that

  • to the horizontal component of the yellow electric field

  • because it also points to the right,

  • even though the charge creating that field is negative,

  • the horizontal component of that field is positive

  • because it points to the right.

  • So if I can get both of these,

  • I will just add these up, and I'd get my total

  • electric field in the x direction.

  • How do I get these?

  • How do I determine these horizontal components?

  • Well, to get the horizontal component

  • of this blue electric field, I first need

  • to find what's the magnitude of this blue electric field.

  • We know the formula for that.

  • I'll write it over here.

  • The magnitude of the electric field

  • is always k Q over r squared.

  • So for this blue field, we'll say that E

  • is equal to nine times 10 to the ninth,

  • and the charge is eight nanoCoulombs.

  • Nano means 10 to the negative ninth.

  • And then we divide by the r, but what's the r in this case?

  • It's not four or three.

  • Remember, the r in that electric field formula

  • is always from the charge to the point you're trying

  • to determine the electric field at.

  • So r is this.

  • This distance is r.

  • How do we figure out what this is?

  • Well, we're kind of in luck.

  • If you know about three, four, five triangles,

  • look at, this forms a three, this side is three,

  • meters, and this side is four meters.

  • That means that this side automatically

  • we know is five meters.

  • If you're not comfortable with that,

  • you can always do the Pythagorean theorem.

  • Pythagorean theorem says that a squared

  • plus b squared equals c squared for a right triangle,

  • which is what we have here.

  • A is this side, three.

  • B is the four meter side.

  • And then c would be r, I'll call that r squared.

  • And if you solve this for r, nine plus 16,

  • square root gives you r is five meters, just like we said.

  • But if you know three, four, five triangles,

  • it's kinda nice because you could just quote that.

  • And that's the r we're gonna use up here.

  • We'll use five meters squared,

  • which, if you calculate, you get

  • that the electric field is 2.88 Newtons per Coulomb.

  • This is the magnitude of the electric field

  • created at this point, P, by the positive charge.

  • How do we get the horizontal component of that field?

  • There's a few ways to do it.

  • One way to do it is first just find this angle here.

  • If we could find what that angle is,

  • we can do trigonometry to get this horizontal component.

  • How do I find this angle?

  • Well, you note that that angle's gonna be

  • the same as this angle down here.

  • These are gonna be similar angles

  • because I've got horizontal lines

  • and then this diagonal line just continues right through.

  • So this angle is the same as this angle,

  • so if I could find this angle here,

  • I've found that angle up top.

  • How do I get this angle?

  • I know each side of this triangle,

  • so I can use either sine, cosine, or tangent.

  • I'm just gonna use tangent.

  • We'll say that tangent of that angle

  • is defined always to be the opposite over adjacent.

  • We know the opposite side to this angle

  • is four meters, and the adjacent side was three meters,

  • so tangent theta's gonna equal 4/3.

  • How do we get theta?

  • We say that theta's going to equal

  • the inverse tangent of 4/3.

  • We basically take inverse tangent of both sides.

  • We get theta on the left, and if you plug this

  • into your calculator, you get 53.1 degrees.

  • So that's what this angle is right here.

  • This is 53.1 degrees, but that means this angle up here

  • is also 53.1 degrees because these are the same angle.

  • This horizontal component is not the same

  • as this three meters?

  • And this diagonal electric field is not the same

  • as five meters, but the angle between those components

  • are the same as the angle between these length components.

  • So what do I do to get this horizontal component?

  • This is the adjacent side to this angle,

  • so this E x is adjacent to that angle.

  • We're gonna use cosine.

  • We're gonna say that cosine of 53.1 degrees

  • is gonna be equal to the adjacent side, which is E x.

  • We'll write this as E x divided

  • by the hypotenuse, and we found the hypotenuse.

  • This is the magnitude of the total

  • electric field right here, which is the hypotenuse

  • of this triangle, so that's 2.88.

  • And we get that E x is going to be 2.88 Newtons

  • per Coulomb times cosine of 53.1,

  • which, if you plug that into the calculator

  • is gonna give you 1.73 Newtons per Coulomb.

  • This is how much electric field

  • the positive charge creates in the x direction.

  • That's what this component up here is.

  • This is 1.73 Newtons per Coulomb.

  • So that's what this is.

  • That's what I'm gonna plug in here.

  • To get this horizontal component

  • of the yellow field created by the negative charge,

  • you could go through the whole thing again

  • or you could notice that because

  • of symmetry, this horizontal component

  • has to be the exact same as the horizontal component

  • created by the positive charge.

  • They're both 1.73, and they're both positive

  • because both of these components point to the right.

  • So to get the total electric field

  • in the x direction, we'll take 1.73

  • from the positive charge and we'll add that

  • to the horizontal component from the negative charge,

  • which is also positive 1.73, to get

  • a horizontal component in the x direction

  • of the net electric field equal to

  • 3.46 Newtons per Coulomb.

  • This is the horizontal component

  • of the net electric field at that point.

  • We basically took both of these values and added them up,

  • which, essentially is just one of them times two.

  • And now you might be worried though, this is just

  • the horizontal component of the net electric field.

  • How do we get the magnitude of the total net electric field?

  • Well, this is gonna be the same value

  • because since there was no vertical component

  • of the electric field, the horizontal component

  • is gonna be equal to the magnitude

  • of the total electric field at that point.

  • If there was a vertical component

  • of the electric field, we'd have

  • to do the Pythagorean theorem to get the total magnitude

  • of the net electric field, but since there was only

  • a horizontal component, and these

  • vertical components canceled, the total electric field's

  • just gonna point to the right, and it will be equal

  • to two times one of these horizontal components,

  • which, when you add them up,

  • gives you 3.46 Newtons per Coulomb.

  • That's the magnitude of the net electric field,

  • and the direction would be straight to the right.

  • So recapping, when you have a 2D electric field problem,

  • draw the field created by each charge,

  • break those fields up into their individual components.

  • If there's any symmetry involved,

  • figure out which component cancels,

  • and then to find the net electric field,

  • use the component that doesn't cancel,

  • and determine the contribution

  • from each charge in that direction.

  • Add or subtract them accordingly,

  • based on whether those components point

  • to the right or to the left, and that will give you

  • your net electric field at that point,

  • created by both charges.

- [Instructor] Let's try a hard one.

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Net electric field from multiple charges in 2D | Physics | Khan Academy

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    yukang920108 に公開 2022 年 07 月 19 日
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