Electrons flow in the direction opposite to the flow of current

In summary, electric current always travels in a loop, with the direction of current being determined by the movement of positive charges. This is why electrons, which have a negative charge, do not get vanished when we switch on a fan and current flows from the switch board to the fan. This is due to the fact that there are two wires in the fan's power cord, with current flowing in opposite directions in each wire. This convention was established by Benjamin Franklin and may seem arbitrary, but it has been used since before the discovery of electrons.
  • #1
debojit das
2
0
Its said that electrons flow in the direction opposite to the flow of current;then why does electron never get vanished when we switch on a fan and current flows from switch board to fan?
 
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  • #2


debojit das said:
Its said that electrons flow in the direction opposite to the flow of current;then why does electron never get vanished when we switch on a fan and current flows from switch board to fan?

There's not only current traveling to the fan, but there is the same amount of current traveling away from the fan. Electric current always travels in a loop; with batteries, wires, fans, natural-gas burning power plants, etc., forming the different parts of the loop. That's why the fan turns on when you hit the switch, because you complete the loop. Breaking the loop (by opening the switch) turns the fan off.

That's why there are two wires in the fan's power cord -- at any instant in time, current is flowing in a given direction in one wire, and the opposite direction in the other wire. When you plug the fan cord into the wall, the two terminals make connections with other parts of the loop.

We have Benjamin Franklin to thank for the fact that electrons travel in the opposite direction as the current. He defined the convention of positive vs. negative charge, thus corresponding current flow. The decision was rather arbitrary at the time. But we can't blame him; the convention was made long before electrons were even discovered.
 
  • #3


Regarding the direction of the current: a current can be created using positive or negative particles. By historical convention the direction of current is determined by the movement of positive charges. Because electricity is the movement of (negative) electrons, the current "flow" is opposite the movement of the electrons.

-David
 

1. What is the direction of electron flow?

The direction of electron flow is opposite to the direction of current flow. This means that when current flows from positive to negative, electrons are actually moving from negative to positive.

2. Why is electron flow opposite to current flow?

This is because historically, scientists thought that current flowed from positive to negative. However, it was later discovered that electrons are the actual charge carriers and they move in the opposite direction of conventional current flow.

3. How does this relate to circuit diagrams?

In circuit diagrams, current is typically represented as flowing from positive to negative. This is a convention that was established before the discovery of electrons. So even though electrons are actually flowing in the opposite direction, the circuit diagrams still show current flowing in the conventional direction.

4. Does this mean that electrons always flow in the opposite direction of current?

Yes, electrons always flow in the direction opposite to the flow of current. This is a fundamental principle in understanding the behavior of electricity and is consistent throughout all circuits and electrical systems.

5. How does this concept apply to other forms of energy?

While the concept of electron flow being opposite to current flow is specific to electricity, the idea of something moving in a direction opposite to the flow of energy can be seen in other forms of energy. For example, in a heat transfer, heat always flows from hot to cold, which is the opposite direction of the energy transfer.

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