A question about electrons, charges and current
Let's talk about DC, a very simple circuit: a light bulb and a battery.
Some authors say that electrons move from negative to positive and current from positive from negative.
I always thought electrons moved in a wire at the light speed, but this video says that charges move very slow in a wire, about 5 centimeter per hour (2 inches per hour).
If electrons are charge carriers, is this video saying that electrons move at 5 cm/hour????
If electrons are that slow how can circuits work?
The video says that electric fields move at light speed.
So, I am not understanding anything.
I aways thought the whole magic were dome by electrons...
What is the correct explanation for this?
Charges, electrons and current?
Is the effect similar to a newton cradle, where one ball knocks the first one and the force is transmitted through the chain?
current charge theory electron
add a comment |
Let's talk about DC, a very simple circuit: a light bulb and a battery.
Some authors say that electrons move from negative to positive and current from positive from negative.
I always thought electrons moved in a wire at the light speed, but this video says that charges move very slow in a wire, about 5 centimeter per hour (2 inches per hour).
If electrons are charge carriers, is this video saying that electrons move at 5 cm/hour????
If electrons are that slow how can circuits work?
The video says that electric fields move at light speed.
So, I am not understanding anything.
I aways thought the whole magic were dome by electrons...
What is the correct explanation for this?
Charges, electrons and current?
Is the effect similar to a newton cradle, where one ball knocks the first one and the force is transmitted through the chain?
current charge theory electron
One of these days I'll have to write a canonical answer, but see electronics.stackexchange.com/questions/245610/… : basically your intuition that it's like the Newtons cradle is correct. For almost all purposes you should ignore electrons.
– pjc50
11 hours ago
add a comment |
Let's talk about DC, a very simple circuit: a light bulb and a battery.
Some authors say that electrons move from negative to positive and current from positive from negative.
I always thought electrons moved in a wire at the light speed, but this video says that charges move very slow in a wire, about 5 centimeter per hour (2 inches per hour).
If electrons are charge carriers, is this video saying that electrons move at 5 cm/hour????
If electrons are that slow how can circuits work?
The video says that electric fields move at light speed.
So, I am not understanding anything.
I aways thought the whole magic were dome by electrons...
What is the correct explanation for this?
Charges, electrons and current?
Is the effect similar to a newton cradle, where one ball knocks the first one and the force is transmitted through the chain?
current charge theory electron
Let's talk about DC, a very simple circuit: a light bulb and a battery.
Some authors say that electrons move from negative to positive and current from positive from negative.
I always thought electrons moved in a wire at the light speed, but this video says that charges move very slow in a wire, about 5 centimeter per hour (2 inches per hour).
If electrons are charge carriers, is this video saying that electrons move at 5 cm/hour????
If electrons are that slow how can circuits work?
The video says that electric fields move at light speed.
So, I am not understanding anything.
I aways thought the whole magic were dome by electrons...
What is the correct explanation for this?
Charges, electrons and current?
Is the effect similar to a newton cradle, where one ball knocks the first one and the force is transmitted through the chain?
current charge theory electron
current charge theory electron
edited 11 hours ago
asked 11 hours ago
SpaceDog
442213
442213
One of these days I'll have to write a canonical answer, but see electronics.stackexchange.com/questions/245610/… : basically your intuition that it's like the Newtons cradle is correct. For almost all purposes you should ignore electrons.
– pjc50
11 hours ago
add a comment |
One of these days I'll have to write a canonical answer, but see electronics.stackexchange.com/questions/245610/… : basically your intuition that it's like the Newtons cradle is correct. For almost all purposes you should ignore electrons.
– pjc50
11 hours ago
One of these days I'll have to write a canonical answer, but see electronics.stackexchange.com/questions/245610/… : basically your intuition that it's like the Newtons cradle is correct. For almost all purposes you should ignore electrons.
– pjc50
11 hours ago
One of these days I'll have to write a canonical answer, but see electronics.stackexchange.com/questions/245610/… : basically your intuition that it's like the Newtons cradle is correct. For almost all purposes you should ignore electrons.
– pjc50
11 hours ago
add a comment |
2 Answers
2
active
oldest
votes
In a metallic wire, electricity propagates as a field, effectively. Electrons move quickly and literally bump into other atoms which (usually) dislodges another electron. This continues down the conductor so the effects of electrical current are seen very quickly.
This is not how electric currents propagate in a superconductor, though.
In that sense, the velocity of electrical propagation is very fast (in a wire it is typically about 63% of the speed of light for reasons I won't go into here. It is known as the velocity factor).
Electric fields (or more accurately electromagnetic fields) propagate at the speed of light in free space.
Any given electron does not travel very far in each of these short hops, but they do move, and a specific electron will move quite slowly. This is known as drift velocity.
brilliant explanation, thanks!
– SpaceDog
10 hours ago
Superconductors do allow small magnetic fields through known as fluxons.
– Scientist Smith YT
6 hours ago
add a comment |
A very much simplified answer:
Compare the wire to a pipe filled with marbles.
As soon as you push a marble in, immediately another marble pops out of the pipe.
But the marble you have pushed in only travels very slowly towards the end.
Very Good. I was suspecting something like that, thanks!
– SpaceDog
10 hours ago
1
@SpaceDog metals are totally jam-packed with movable electrons. (It's like Ben Franklin's electric fluid! But it's there all the time.) So, an electric circuit is like a drive-belt inside a pipe. That's why currents are closed-loop circles, and require "complete circuits." Notice that the path for current is through the dynamo coils and back out again? Also, the path is through every battery ...so no charge builds up inside. Batteries are "charge pumps," so when we "recharge" them, we're filling them with chemical fuel. (Charged batteries contain just as much electric charge as dead ones!)
– wbeaty
6 hours ago
add a comment |
Your Answer
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2 Answers
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active
oldest
votes
2 Answers
2
active
oldest
votes
active
oldest
votes
active
oldest
votes
In a metallic wire, electricity propagates as a field, effectively. Electrons move quickly and literally bump into other atoms which (usually) dislodges another electron. This continues down the conductor so the effects of electrical current are seen very quickly.
This is not how electric currents propagate in a superconductor, though.
In that sense, the velocity of electrical propagation is very fast (in a wire it is typically about 63% of the speed of light for reasons I won't go into here. It is known as the velocity factor).
Electric fields (or more accurately electromagnetic fields) propagate at the speed of light in free space.
Any given electron does not travel very far in each of these short hops, but they do move, and a specific electron will move quite slowly. This is known as drift velocity.
brilliant explanation, thanks!
– SpaceDog
10 hours ago
Superconductors do allow small magnetic fields through known as fluxons.
– Scientist Smith YT
6 hours ago
add a comment |
In a metallic wire, electricity propagates as a field, effectively. Electrons move quickly and literally bump into other atoms which (usually) dislodges another electron. This continues down the conductor so the effects of electrical current are seen very quickly.
This is not how electric currents propagate in a superconductor, though.
In that sense, the velocity of electrical propagation is very fast (in a wire it is typically about 63% of the speed of light for reasons I won't go into here. It is known as the velocity factor).
Electric fields (or more accurately electromagnetic fields) propagate at the speed of light in free space.
Any given electron does not travel very far in each of these short hops, but they do move, and a specific electron will move quite slowly. This is known as drift velocity.
brilliant explanation, thanks!
– SpaceDog
10 hours ago
Superconductors do allow small magnetic fields through known as fluxons.
– Scientist Smith YT
6 hours ago
add a comment |
In a metallic wire, electricity propagates as a field, effectively. Electrons move quickly and literally bump into other atoms which (usually) dislodges another electron. This continues down the conductor so the effects of electrical current are seen very quickly.
This is not how electric currents propagate in a superconductor, though.
In that sense, the velocity of electrical propagation is very fast (in a wire it is typically about 63% of the speed of light for reasons I won't go into here. It is known as the velocity factor).
Electric fields (or more accurately electromagnetic fields) propagate at the speed of light in free space.
Any given electron does not travel very far in each of these short hops, but they do move, and a specific electron will move quite slowly. This is known as drift velocity.
In a metallic wire, electricity propagates as a field, effectively. Electrons move quickly and literally bump into other atoms which (usually) dislodges another electron. This continues down the conductor so the effects of electrical current are seen very quickly.
This is not how electric currents propagate in a superconductor, though.
In that sense, the velocity of electrical propagation is very fast (in a wire it is typically about 63% of the speed of light for reasons I won't go into here. It is known as the velocity factor).
Electric fields (or more accurately electromagnetic fields) propagate at the speed of light in free space.
Any given electron does not travel very far in each of these short hops, but they do move, and a specific electron will move quite slowly. This is known as drift velocity.
answered 11 hours ago
Peter Smith
13.6k11237
13.6k11237
brilliant explanation, thanks!
– SpaceDog
10 hours ago
Superconductors do allow small magnetic fields through known as fluxons.
– Scientist Smith YT
6 hours ago
add a comment |
brilliant explanation, thanks!
– SpaceDog
10 hours ago
Superconductors do allow small magnetic fields through known as fluxons.
– Scientist Smith YT
6 hours ago
brilliant explanation, thanks!
– SpaceDog
10 hours ago
brilliant explanation, thanks!
– SpaceDog
10 hours ago
Superconductors do allow small magnetic fields through known as fluxons.
– Scientist Smith YT
6 hours ago
Superconductors do allow small magnetic fields through known as fluxons.
– Scientist Smith YT
6 hours ago
add a comment |
A very much simplified answer:
Compare the wire to a pipe filled with marbles.
As soon as you push a marble in, immediately another marble pops out of the pipe.
But the marble you have pushed in only travels very slowly towards the end.
Very Good. I was suspecting something like that, thanks!
– SpaceDog
10 hours ago
1
@SpaceDog metals are totally jam-packed with movable electrons. (It's like Ben Franklin's electric fluid! But it's there all the time.) So, an electric circuit is like a drive-belt inside a pipe. That's why currents are closed-loop circles, and require "complete circuits." Notice that the path for current is through the dynamo coils and back out again? Also, the path is through every battery ...so no charge builds up inside. Batteries are "charge pumps," so when we "recharge" them, we're filling them with chemical fuel. (Charged batteries contain just as much electric charge as dead ones!)
– wbeaty
6 hours ago
add a comment |
A very much simplified answer:
Compare the wire to a pipe filled with marbles.
As soon as you push a marble in, immediately another marble pops out of the pipe.
But the marble you have pushed in only travels very slowly towards the end.
Very Good. I was suspecting something like that, thanks!
– SpaceDog
10 hours ago
1
@SpaceDog metals are totally jam-packed with movable electrons. (It's like Ben Franklin's electric fluid! But it's there all the time.) So, an electric circuit is like a drive-belt inside a pipe. That's why currents are closed-loop circles, and require "complete circuits." Notice that the path for current is through the dynamo coils and back out again? Also, the path is through every battery ...so no charge builds up inside. Batteries are "charge pumps," so when we "recharge" them, we're filling them with chemical fuel. (Charged batteries contain just as much electric charge as dead ones!)
– wbeaty
6 hours ago
add a comment |
A very much simplified answer:
Compare the wire to a pipe filled with marbles.
As soon as you push a marble in, immediately another marble pops out of the pipe.
But the marble you have pushed in only travels very slowly towards the end.
A very much simplified answer:
Compare the wire to a pipe filled with marbles.
As soon as you push a marble in, immediately another marble pops out of the pipe.
But the marble you have pushed in only travels very slowly towards the end.
answered 11 hours ago
Oldfart
7,9462825
7,9462825
Very Good. I was suspecting something like that, thanks!
– SpaceDog
10 hours ago
1
@SpaceDog metals are totally jam-packed with movable electrons. (It's like Ben Franklin's electric fluid! But it's there all the time.) So, an electric circuit is like a drive-belt inside a pipe. That's why currents are closed-loop circles, and require "complete circuits." Notice that the path for current is through the dynamo coils and back out again? Also, the path is through every battery ...so no charge builds up inside. Batteries are "charge pumps," so when we "recharge" them, we're filling them with chemical fuel. (Charged batteries contain just as much electric charge as dead ones!)
– wbeaty
6 hours ago
add a comment |
Very Good. I was suspecting something like that, thanks!
– SpaceDog
10 hours ago
1
@SpaceDog metals are totally jam-packed with movable electrons. (It's like Ben Franklin's electric fluid! But it's there all the time.) So, an electric circuit is like a drive-belt inside a pipe. That's why currents are closed-loop circles, and require "complete circuits." Notice that the path for current is through the dynamo coils and back out again? Also, the path is through every battery ...so no charge builds up inside. Batteries are "charge pumps," so when we "recharge" them, we're filling them with chemical fuel. (Charged batteries contain just as much electric charge as dead ones!)
– wbeaty
6 hours ago
Very Good. I was suspecting something like that, thanks!
– SpaceDog
10 hours ago
Very Good. I was suspecting something like that, thanks!
– SpaceDog
10 hours ago
1
1
@SpaceDog metals are totally jam-packed with movable electrons. (It's like Ben Franklin's electric fluid! But it's there all the time.) So, an electric circuit is like a drive-belt inside a pipe. That's why currents are closed-loop circles, and require "complete circuits." Notice that the path for current is through the dynamo coils and back out again? Also, the path is through every battery ...so no charge builds up inside. Batteries are "charge pumps," so when we "recharge" them, we're filling them with chemical fuel. (Charged batteries contain just as much electric charge as dead ones!)
– wbeaty
6 hours ago
@SpaceDog metals are totally jam-packed with movable electrons. (It's like Ben Franklin's electric fluid! But it's there all the time.) So, an electric circuit is like a drive-belt inside a pipe. That's why currents are closed-loop circles, and require "complete circuits." Notice that the path for current is through the dynamo coils and back out again? Also, the path is through every battery ...so no charge builds up inside. Batteries are "charge pumps," so when we "recharge" them, we're filling them with chemical fuel. (Charged batteries contain just as much electric charge as dead ones!)
– wbeaty
6 hours ago
add a comment |
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One of these days I'll have to write a canonical answer, but see electronics.stackexchange.com/questions/245610/… : basically your intuition that it's like the Newtons cradle is correct. For almost all purposes you should ignore electrons.
– pjc50
11 hours ago