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Electrostatic shielding & Faraday cage

Let's explore why electric fields cannot penetrate a closed conductor. This makes a closed conductor shield the inside from outside electric fields. They are useful in protecting sensitive electronic equipment's from stray fields. This effect was first studied by Michael Faraday, and hence closed conductors are often called Faraday cages. Created by Mahesh Shenoy.

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  • blobby green style avatar for user bhaiy4658
    In lightining when electrons enter the surface of conductor then why it would not the change electric field inside a conductor ?as it carries electrons
    (2 votes)
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  • blobby green style avatar for user suryanshg10
    I have a doubt at
    why is it compulsory for the person to touch the inside surface?😅
    (1 vote)
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  • piceratops seed style avatar for user Adamaubry2362
    you say at that the field inside the conductor matches and exactly cancels with the external field. So why is there still not a field inside the conductor then? Isn't the one that cancels out the external field consider a field? I realize that you said said the net field was 0 so I guess the way that I am thinking about it is that the external field is what causes the field inside to be opposite and without it their is no field to begin with inside. I guess I am more confused when you mention the work being zero and the equipotential to be zero. Like since there is an electric field inside that is canceling out the external field wouldn't that still cause their to be a potential difference between two points?
    (1 vote)
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  • blobby green style avatar for user hariomss0312
    at since electrons are in electrostatic condition so they are not movinig i.e E=0,
    how you know that after placing a point charge near the conductor the electrons of the conductor will move and rearrange themselve in such a way that they will again come in electrostatic condition
    because according to me for elctrostatic condn electrons must be in a certain fixed positions
    but electrons cannot be in any fixed position they are movable
    (1 vote)
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Video transcript

[Music] this picture shows a girl a couple of girls standing inside a metallic cage and somebody is trying to electrocute them using lightning and nothing seems to be happening to them she seems happy why now if you're thinking hey maybe the electricity is not much over here maybe it's a very tiny spark well the same effect can be reproduced using you know millions of volts lightning which produced due to millions of volts of potential difference using what we call tesla coils and you can see the same effect people inside a cage lightning is striking that cage but nothing happens to them why well metallic cages are basically conductors so let's explore how conductors deal with electric fields and maybe we'll be able to answer this question by the end of the video say we have a positive charge kept somewhere in space and close to it we're going to keep a spherical conductor imagine a metallic sphere with a hole inside of it with a cavity inside and let's say it's neutral the question now is if we are in electrostatic conditions meaning there are no moving charges how would the electric field change due to the presence of this conductor we can begin by asking why should the electric field even change because we have kept a conductor now well here's the thing conductors have free electrons inside of them and so if you consider a free electron somewhere over here because there's an electric field it's going to put a force on this electron because it's negative the force would be in the opposite direction of the field direction and as a result this electron would start moving but we said hey we want to be in electrostatic condition which means this cannot be in electrostatic conditions in this condition electrons will start moving so again the question is if no electrons are moving how the field look like can you pause the video at this point and try to give it a shot try to think about how the new field would look like all right so if we don't want any electrons to move the condition is simple there shouldn't be any electric field inside the conductor so in electrostatic situation the field inside the conductor must be zero so we can go ahead and we can delete the field inside so let me just rub this field so the field inside must be zero then and only then this electron will electrons inside the conductor will no longer experience a force and this is nothing special there's nothing special about a spherical conductor this has to be true for any conductor which means we can now go ahead and write a general conclusion in electrostatic conditions electric field inside any conductor must be zero but you could ask well what exactly is happening what's happening to that electric field and well here's how i like to think about it we now we've already seen these electrons are gonna when there was a field over here the electrons start migrating towards the positive charge and as a result they end up coming somewhere over here they can't move outside the conductor because it's an insulator imagine it's vacuum so they'll all get migrated somewhere over here so all our negative charge will get accumulated over here and because this is a neutral conductor if the negative charge is accumulated over here it must have left a positive charge somewhere and whenever there's a positive charge more electrons would just keep accumulating eventually there will be a positive charge somewhere on the outer surface of this conductor somewhere like this so that the total charge on the conductor must still be zero charge conservation we cannot create or destroy charges and because of this positive and negative separation they are now going to start producing producing their own field they're going to start producing a field inside let me use a different color for that let's say i'm going to use blue to represent the field that they have generated so they might generate a positive negative field that would look like this and guess what this field the internal field exactly matches and cancels with the external field and because of that the total field goes to zero now you may ask how do you know that it exactly matches well it has to because if it didn't if it didn't exactly match and it didn't go to zero electrons would still be moving so think of it this way the electrons will keep moving until the electric field generated inside matches and cancels out with the electric field from the outside making sure that the net electric field inside the conductor has to be zero beautiful right so is this how our electric field is going to look like no not really we're still not done yet and things are going to get more interesting now now think about this because electric field everywhere is zero this means that our entire conductor must be an equipotential surface meaning that every single point on the surface or inside the surface inside the conductor should have the exact same potential now again i want you to pause the video and think a little bit about why should this be the case why if we say electric field is zero it should be an equipotential surface can you make try and make that link yourself all right here's how i like to think about it consider any two points on this conductor maybe say one point inside over here maybe another point inside the cavity somewhere over here now imagine you have to take a you know a charge from point a to point b in doing so how much work would you do well think about it there is no electric field inside if there's no electric field inside you don't have to do any work against the electric field which means you do zero work and that should be true for any two points so let me write that down this means the work done in moving any charge between any two random points a and b should be zero in other words potential at a must be exactly equal to potential at b and a and b can be any two points on the surface inside inside the cavity any two points because there are no electric fields and what does that mean that means the potential everywhere must be the same meaning our entire conductor is an equipotential surface so another interesting thing we see is that in electrostatic conditions conductors the entire conductor must be an equipotential again nothing special about spherical conductors over here all conductors should obey this rule but you may ask okay how does that affect our electric field well remember one property of an equipotential surface these surfaces must always always be perpendicular to electric field and if you're wondering why should this be the case we've spoken about this in great great detail in a previous video on equipotential surfaces so feel free to go back and check that out but here's the thing over here if you look now this means that all these field lines which are touching our conductor must be perpendicular to the surface and they're not over here also notice they are not perpendicular this angle this angle these are not perpendicular so somehow the field lines must change must bend to ensure this is true everywhere on the surface so again can you pause the video now for one last time and think about you know try to draw a sketch of what this would look like all right here we go so the field lines must bend in such a way as to they are perpendicular at every point they are meeting the conductor and so if you look at this this means that this conductor is sort of like sucking the electric field and that's why even these field lines are going to sort of sort of like bend towards their conductor because they can sort of like getting sucked look at how complicated this situation has quickly gotten but we now understand that we understand why this has to be true because it's an equipotential surface because of some basic rules that that we had learned earlier now let's see if we can answer the original question imagine this field was incredibly strong and there was air over here in such cases you can get lightning and we'll talk more about how that happens and all that fun stuff in the future videos but let's say there is this lightning strike happens now where will that lightning go can it enter inside the conductor well remember lightning is basically charges moving in an electric field now if there is no electric field inside a conductor the charges will not move inside the conductor so what will happen is that these you know these elect these electrons or these charges will find a way to go through the surface and eventually somehow go into the ground this means if there was somebody standing inside the conductor and let's say she was touching touching the inner surface she will not be electrocuted by that lightning now here it doesn't look so dramatic because it's a thick conductor but the same thing would work even if it was an incredibly thin conductor that's exactly what's happening over here this is a completely a closed conductor electric fields cannot penetrate inside this conductor because of which when she's touching the inner surface the lightning cannot enter the surface and that's why she's not getting electrocuted this effect is called electrostatic shielding because as you can see the inner surface is shielded the shielded from the outer electrostatics and this was first discovered by michael faraday and so a closed metallic conductor is often also called a faraday gauge so we would say that these girls are standing inside a faraday cage which is shielding them from the outside electrostatics and that's why they're not getting electrocuted this is also the reason why airplanes can get struck by lightning and nothing will happen to the inside because an entire aeroplane is a metallic body it acts like a faraday cage and therefore lightning will not penetrate in most cases even when the lightning strikes an aeroplane nothing it doesn't damage it doesn't do any damage