Velocity of electrons in a wire

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Electrons in a wire move in various directions, resulting in a net electric charge cancellation. When voltage is applied, a small number of electrons move in the direction of the voltage, known as drift speed, which is typically very slow. Despite this slow drift speed, the high density of free electrons in a wire allows for significant current flow, as a large number of electrons can pass a point in a short time. A current of 1 ampere requires 6.25 x 10^18 electrons to move past a point each second, which is feasible due to the vast number of electrons present. This concept is effectively illustrated by a toy that shows how a chain of balls can transmit motion quickly while individual balls hardly move.
moment1337
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Electrons are moving in moves in all sorts of directions, causing the net electric charge to cancel out. But, when you apply a voltage, there's a small amount of electrons that will move towards the direction in the direction of the voltage. This is called the drift speed. Am I right? I read that the drift speed usually is 1/10000 of a second. How can you then obtain a current of 1 ampere, when 6.25*10^18 electrons has to move past a single point in one second, when the drift speed of the charge is that slow?
 
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moment1337 said:
a small amount of electrons
There are lots of free electrons in a typical wire.

moment1337 said:
How can you then obtain a current of 1 ampere, when 6.25*10^18 electrons has to move past a single point in one second, when the drift speed of the charge is that slow?
Lots of electrons!

See: Microscopic View of Electric Current
 
Oh I see now. So the drift velocity of a single electron might be very slow, but because there are 8.5 * 10^28 electrons in a wire point of the wire, you still can get a pretty high current flow?
 
moment1337 said:
Oh I see now. So the drift velocity of a single electron might be very slow, but because there are 8.5 * 10^28 electrons in a wire point of the wire, you still can get a pretty high current flow?

200px-Newtons_cradle_animation_book_2.gif

Have you seen this toy? It demonstrates the concept nicely. The time from an ball enters the ball chain to the end ball bouncing out is very short - but the internal balls (like the electrons in the wire) hardly move at all.
 
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Svein said:
200px-Newtons_cradle_animation_book_2.gif

Have you seen this toy? It demonstrates the concept nicely. The time from an ball enters the ball chain to the end ball bouncing out is very short - but the internal balls (like the electrons in the wire) hardly move at all.

Bravo Svein. This question comes up frequently on PF. That little video you posted explains it better than 10,000 words.
 
moment1337 said:
Oh I see now. So the drift velocity of a single electron might be very slow, but because there are 8.5 * 10^28 electrons in a wire point of the wire, you still can get a pretty high current flow?
Exactly.
 

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