How should one interpret ##\vec{f}=0## in an ideal battery?

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Discussion Overview

The discussion revolves around the interpretation of the equation ##\vec{f}=0## within the context of an ideal battery in a circuit. Participants explore the implications of this equation on the movement of charges, the relationship between force and current, and the behavior of electric fields in the battery when a circuit is closed.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested

Main Points Raised

  • Some participants propose that in an ideal battery, the forces acting on charges, namely the electrostatic field ##\vec{E}## and the field produced by chemical reactions ##\vec{f_s}##, oppose each other, resulting in ##\vec{f}=0##.
  • Others argue that ##\vec{f}=0## indicates that charges are not accelerating, but this does not imply they are not moving.
  • One participant questions how current can be produced if the net force on the charges is zero, suggesting that charges might move randomly and cancel out any current.
  • Another participant clarifies that if the net force is zero, charges will continue moving in a straight line at a constant speed.
  • There is a discussion about the effect of closing a circuit on the outside of the battery, which participants note changes the net electric field and can start pushing charges through the battery.
  • Some participants express confusion regarding the assumptions made in textbooks about the state of the circuit when discussing these concepts.

Areas of Agreement / Disagreement

Participants do not reach a consensus on the interpretation of ##\vec{f}=0## and its implications for charge movement and current production. Multiple competing views remain regarding the relationship between force, motion, and current in the context of an ideal battery.

Contextual Notes

Participants highlight the lack of distinction in some textbooks regarding whether the circuit is open or closed, which may affect the interpretation of the forces and fields involved.

ghostfolk
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In a circuit there are two forces that act on the charges to keep the current uniform through out,
##\vec{f}=\vec{E}+\vec{f_s}##, where ##\vec{E}## is the electrostatic field and ##\vec{f_s}## is the electric field produced by chemical reactions. Inside an ideal battery, ##\vec{E}## and ##\vec{f_s}##, oppose each other such that ##\vec{f}##, is zero. What exactly would be the correct way of thinking of ##\vec{f}=0##? I mean obviously the charges are moving, but it looks like in the battery they are not.
 
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I don't think that this is a correct analysis, but f=0 would imply that the charge is not accelerating rather than that it is not moving.
 
DaleSpam said:
I don't think that this is a correct analysis, but f=0 would imply that the charge is not accelerating rather than that it is not moving.
I got it from Griffiths' Introduction to Electrodynamics. I know that would imply the charges are still moving, but how do I know that current is being produced?
 
ghostfolk said:
I know that would imply the charges are still moving, but how do I know that current is being produced?
Current = charges moving. They are the same thing. If you know that the charges are moving then you automatically know that there is current.
 
DaleSpam said:
Current = charges moving. They are the same thing. If you know that the charges are moving then you automatically know that there is current.
But if the net force on the charges are zero, shouldn't the charges move about randomly cancelling out any current?
 
No. If the net force is zero then they continue in a straight line at a constant speed.
 
DaleSpam said:
No. If the net force is zero then they continue in a straight line at a constant speed.
So how do I know they started in a straight line?
 
ghostfolk said:
Inside an ideal battery, E⃗ \vec{E} and fs→\vec{f_s}, oppose each other such that f⃗ \vec{f}, is zero.
Yes, but the moment you close a circuit on the outside of the battery, the current reduces the charge and thereby the electric field. The net field will then be different from 0 and start pushing charges through the battery.
 
Svein said:
Yes, but the moment you close a circuit on the outside of the battery, the current reduces the charge and thereby the electric field. The net field will then be different from 0 and start pushing charges through the battery.
Ohh okay. You see in the textbook I was reading, it made no distinction as to whether or not the circuit was open.
 

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