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William John
William John
05:31
A spherical shell of uniform charge density $\sigma$ has a circular hole cut out of it as shown below:
user image
What is the Electric Field at a radius just outside the sphere, directly over the center of the circular, cut-out hole? Type "sigma" for $\sigma$ and "epsilon_o" for $\epsilon_{o}$

. HINT: the hole is small enough that you can treat it as flat, and the point at which you are calculating the field is so close to the hole that it can be approximated as an infinite plane
I used superposition principle. I first calculated the electric field of sphere then subtracted it from disc which will act as infinite plate.
My answer was $\frac{\sigma}{2\epsilon_0}$.
Why am I wrong?
Aarushi Agarwal
Aarushi Agarwal
05:55
Hi
John Rennie
John Rennie
Hi :-)
William John
William John
;_;
Aarushi Agarwal
Aarushi Agarwal
Are you familiar with Feynman's reflection probability amplitude experiment
William John
William John
Nope
Aarushi Agarwal
Aarushi Agarwal
Where it involves assuming that light can be reflected from all parts of the mirror reaching the photon detector
@JohnRennie I had a doubt in that
John Rennie
John Rennie
06:04
@AarushiAgarwal This sounds like Huygen's construction.
Aarushi Agarwal
Aarushi Agarwal
not familiar with that
ohh got it , i wasn't familiar with the term basically Young's experiment right?
John Rennie
John Rennie
You mean Young's slits?
Aarushi Agarwal
Aarushi Agarwal
yeah
every point on the wavefront acts as a secondary source of waves
John Rennie
John Rennie
Yes. Feynman made quite a nice point about this.
Aarushi Agarwal
Aarushi Agarwal
i having trouble comprehending that
John Rennie
John Rennie
06:08
Suppose you consider light passing through a surface (or reflecting from a surface as in a mirror).
If the Young's slits experiment we have a solid surface that blocks the light and we put two slits in it.
Aarushi Agarwal
Aarushi Agarwal
ok
John Rennie
John Rennie
So the light on the other side of the surface only comes from the two slits, and we can fairly easily calculate how the light from those two slits combines to create the light and dark fringes we see in the YS experiment.
Aarushi Agarwal
Aarushi Agarwal
yeah
John Rennie
John Rennie
Now suppose we put in a third slit.
Aarushi Agarwal
Aarushi Agarwal
ok
John Rennie
John Rennie
06:10
Now we add up the light from the three slits. This is a little more complicated but not terrible.
Aarushi Agarwal
Aarushi Agarwal
ok
John Rennie
John Rennie
We get a slightly different pattern of fringes.
And now we can add a fourth slit, then a fifth and so on. Each time we get the pattern by summing up the light from all the slits.
Aarushi Agarwal
Aarushi Agarwal
ok
John Rennie
John Rennie
But suppose we add so many slits that the slits completely fill the plane i.e. all the light hitting the plane goes through.
Aarushi Agarwal
Aarushi Agarwal
yeah
John Rennie
John Rennie
06:13
Now we just have a light beam travelling through space because there is no longer anything in the way. But we can still calculate the how the light travels by adding up all the slits.
And this is Huygens' construction.
You can predict how light will travel by treating every point on a surface as a point source and adding up the light emitted by all those point sources.
It seems weird but it does kind of make sense.
Aarushi Agarwal
Aarushi Agarwal
hmmn
let me think it over
John Rennie
John Rennie
OK :-)
Aarushi Agarwal
Aarushi Agarwal
@JohnRennie would there any interference in that case? since there will be billions of point of sources
on a surface
John Rennie
John Rennie
Yes, but they interfere to give a uniform brightness instead of fringes.
Aarushi Agarwal
Aarushi Agarwal
@John Rennie would those interference result in the same wavefront being formed?
John Rennie
John Rennie
06:20
Yes.
Which is what happens of course when a light wave travels through empty space.
Aarushi Agarwal
Aarushi Agarwal
yeah
but but
i was talking reflection
tho
there was this diagram
I couldn't comprehend
" I can't send images here " , so search " Feynman reflection diagram " and u might see it
John Rennie
John Rennie
Reflection is actually the same as transmission except that the light switches direction, so the same argument applies.
Can you post the link to the article or image?
Aarushi Agarwal
Aarushi Agarwal
sure
spaceandmotion.com/Physics-Richard-Feynman-QED.htm
read the reflection part
John Rennie
John Rennie
06:36
user image
Let me draw a quick diagram ...
user image
Aarushi Agarwal
Aarushi Agarwal
ok
John Rennie
John Rennie
On the left we have th situation we were talking about with light passing through a plane.
Aarushi Agarwal
Aarushi Agarwal
one's transmitting and one's reflecting ig ?
yes
John Rennie
John Rennie
An the right we replace the plane with a mirror.
But all the mirror does is flip the vertical motion of the light rays. We can do the calculation on the left adding up all the light rays from all the points on the dashed plane ...
Aarushi Agarwal
Aarushi Agarwal
wait , if the surface hadn't been a mirror , wouldn't it still reflect some part of light?
John Rennie
John Rennie
06:41
... then if we just flip all our rays vertically we would get the diagram on the right.
Aarushi Agarwal
Aarushi Agarwal
yes
John Rennie
John Rennie
@AarushiAgarwal The surface isn't really there is it? Because we started with a solid surface but then replaced the whole surface by slits so that no part of the surface was left.
Aarushi Agarwal
Aarushi Agarwal
oh yeah
John Rennie
John Rennie
So on the left the dashed line is just a plane in space not actually a surface.
Aarushi Agarwal
Aarushi Agarwal
ohh
John Rennie
John Rennie
06:43
But what I'm saying is that if we take all the rays below the dashed line on the left and flip them upwards we get the diagram for the mirror.
I've only drawn one ray, but every ray would be flipped upwards in the same way.
Aarushi Agarwal
Aarushi Agarwal
ohh
yeah
John Rennie
John Rennie
So it's actually exactly the same calculation for both the mirror and the surface.
Aarushi Agarwal
Aarushi Agarwal
ok
then how does it result to the multiple rays reaching a point without obeying the law of reflection?
John Rennie
John Rennie
What happens is that the light moving downwards hits the mirror, then every point on the mirror acts like a point source sending light back upwards again.
Aarushi Agarwal
Aarushi Agarwal
got that
John Rennie
John Rennie
06:47
And when we sum up all those point sources on the mirror we find they create the reflected light.
Aarushi Agarwal
Aarushi Agarwal
hmmn
John Rennie
John Rennie
Just like on the left we sum up all the point sources in the plane and they create the trnasmitted light.
Aarushi Agarwal
Aarushi Agarwal
hmmn
the direction of the rays?
is something im confused bout
is it because of the interference with other waves?
John Rennie
John Rennie
Yes. It isn't obvious how it is going to work out, but when you add up all the point sources you get a well defined direction that is the same as the incident ray for the surface and reflected at the same angle for the mirror.
Aarushi Agarwal
Aarushi Agarwal
ohh
Aarushi Agarwal
Aarushi Agarwal
07:10
You might think I'm crazy, because for most of the ways I told you a photon could reflect off the mirror, the angles aren't equal. But I'm not crazy, because that's the way light really goes. How can that be? ... (Richard Feynman, 1985)
hey @JohnRennie move to this part of the story , thats where my doubt lies?
John Rennie
John Rennie
07:23
To understand this we need to consider what actually happens when a mirror reflects light.
And what happens is that the reflection is really a two step process:
1. the silver atoms in the mirror absorb the light
2. the silver atoms re-emit the light again
So the mirror really is acting like an array of point sources, where the silver atoms re-emitting the light are the point sources.
I think I answered a question on this on the main site ...
31
A: Why is the light reflected at the same angle from mirror?

John RennieThat's a good question. Without realising it you have stumbled across the Huygens-Fresnel principle. The starting point it that a single silver atom is far smaller than the wavelength of light, so any scattering from it will be isotropic i.e. it will scatter the light equally in all directions. ...

Kavin Ishwaran
Kavin Ishwaran
07:51
@JohnRennie Hi !
John Rennie
John Rennie
Hi :-)
Kavin Ishwaran
Kavin Ishwaran
are you free ?
John Rennie
John Rennie
Yes :-)
Kavin Ishwaran
Kavin Ishwaran
I remember you saying light bends because state of medium must be same. can you explain it briefly ?
John Rennie
John Rennie
I don't remember saying that ...
Kavin Ishwaran
Kavin Ishwaran
07:59
I think I have made an error saying what you have said :)
John Rennie
John Rennie
Was this the problem with the refractive index varying with depth?
Kavin Ishwaran
Kavin Ishwaran
no
I once asked about why light refracts
you said... something should be continuous, I dont remember it correctly
John Rennie
John Rennie
Ah, the light is an oscillating electric field. Yes?
Kavin Ishwaran
Kavin Ishwaran
yes
John Rennie
John Rennie
Suppose would take a snapshot of the light wave at a moment in time so we could see how its electric field varied with distance, then we'd get something like this:
user image
Does this make sense?
Kavin Ishwaran
Kavin Ishwaran
08:06
Yes
John Rennie
John Rennie
If the wave is passing through an interface into glass or some other medium then we get this:
user image
The wavelength decreases in the glass.
However, the electric field cannot jump discontinuously at the air glass interface.
Kavin Ishwaran
Kavin Ishwaran
@JohnRennie To my knowledge, the wavelength decreases due to the interaction with the glass's electric field (?)
John Rennie
John Rennie
i.e. it could not do this:
user image
The reason is that if the field changes discontinuously at the interface then it is undefined at the interface.
Kavin Ishwaran
Kavin Ishwaran
I see
John Rennie
John Rennie
So you are probably remembering that I said the electric field must be continuous at the interface.
Kavin Ishwaran
Kavin Ishwaran
08:13
yes
Got it !
So its bending to compensate for the wavelength change without changing the orientation of the wave. right ?
John Rennie
John Rennie
Yes.
cOnnectOrTR 12
cOnnectOrTR 12
HI @JohnRennie I have got a question
John Rennie
John Rennie
The electric field has to be continuous over the whole interface and the only way the light beam can do this is by bending.
@cOnnectOrTR12 Hi :-)
Kavin Ishwaran
Kavin Ishwaran
Thank you for the clarification Sir :-)
 
2 hours later…
William John
William John
10:42
An infinite planar "slab" of charge sits in the x-y plane. It has a thickness of $10cm$ and a volume charge density $ρ=0.005z^2$, where the constant 0.005 has units $C/m^3$ and $z=0$ is the center of the slab. What is the electric field magnitude in $N/C$ at $z=2cm$, inside the slab?
Here is my approach. Since density is $ρ(z)=0.005z^2$ so when I enclose it by 4 by 4 by 4 cube the top and bottom face of cube must have same electric field magnitude so $E=\frac{\int_{-2}^{2}\rho(z)dz}{2\epsilon_0}\approx1.50659\cdot10^9$. I still don't understand why I am wrong here. I am quite confused abou
I think I am not confused about non uniform charged density but the more I think more I get confused.
Aarushi Agarwal
Aarushi Agarwal
11:37
@JohnRennie if it ultimately reduces the current , then how come it is the same , because electrons don't whether there is a resistor , according to me , At the starting there is a 4amperes of current and the electrons reaches the resistor , it feels resistance and the time increases so current reduces because of manipulation of the time without losing electrons
But what if , when it leaves the resistor , the electrons have little to no resistance in the wire , so they move at the original rate or current remains same?
Half-baked theory from my side
Ashish Ahuja
Ashish Ahuja
12:39
@WilliamJohn seems correct to me. Another way to approach this would be to say that the value of electric field due to the cut-out hole is $E_1$ and due to the remaining part is $E_2$. If you "put back" the cut-out hole, it is a regular sphere. So just outside the whole $E_1 + E_2 = \frac{\sigma}{\epsilon_o}$, and just inside $E_1 - E_2 = 0$. Solving these you get the same answer you got
@WilliamJohn looks like you took 2cm as 2m, I'm getting the answer as 1506.59 V/m
Ashish Ahuja
Ashish Ahuja
12:56
@JohnRennie btw, not exactly related to this, but some light also reflects from the glass surface; at a certain angle the reflected light is completely polarized and I remember something about which direction wrt to the plane of incidence it is polarized in. I did not really understand what was happening, so could you explain why exactly reflected light at brewsters angle is completely polarized?
And also in which direction does it get polarized?
 
2 hours later…
William John
William John
14:27
@AshishAhuja Ah this time I messed up lol. Thanks for feedback.
Yes you are right.
@AshishAhuja Yeah I had same thought.
Thanks again for the reply :)
William John
William John
14:49
Two charged conducting sphere with charges +q and -q separated by distance d. The force between them is greater than $kq^2/d^2$ right?
Is it because without one of the conductor presence extra charge goes to surface and then if we present the other conductor then the force will pull each other with greater force because they will move the charge little bit closer to each other?
Charge is free to move in conductor

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