Why Does a Charged Ruler Attract a Current-Carrying Wire?

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Discussion Overview

The discussion revolves around the interaction between a charged plastic ruler and a current-carrying wire, exploring the nature of the forces involved, including electrostatic and magnetic effects. Participants examine the implications of charge movement and the conditions under which attraction or repulsion may occur.

Discussion Character

  • Exploratory
  • Debate/contested
  • Technical explanation

Main Points Raised

  • One participant describes an experiment where a charged ruler attracts a current-carrying wire, questioning why this attraction persists even when the current direction changes.
  • Another participant asserts that the electrons on the ruler are stationary, emphasizing that there is no current in the insulator, which leads to a lack of magnetic force.
  • A participant suggests that the stationary electrons on the ruler should influence the moving electrons in the wire, raising questions about the expected magnetic forces.
  • Some participants argue that the attractive force is purely electrostatic, induced by the charge on the ruler, and not influenced by the current in the wire.
  • One participant introduces the Lorentz force equation to discuss how the charge on the ruler could influence the current in the wire, suggesting a transformation into different frames of reference.
  • Another participant mentions that if the wire has capacitance and voltage, it could either attract or repel the ruler, depending on the charge distribution.

Areas of Agreement / Disagreement

Participants express differing views on the nature of the forces at play, with some emphasizing electrostatic interactions and others questioning the role of magnetic forces. There is no consensus on the overall explanation for the observed attraction or potential repulsion.

Contextual Notes

Participants reference concepts such as Gauss's law, the Lorentz force equation, and the behavior of charges in different frames of reference, indicating a complex interplay of factors that remain unresolved.

crx
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I set up a simple experiment where a dc current carrying bare wire conductor runs parallel with a electrically charged plastic ruler. When no current flows in the wire and the ruler is charged with electrons (by rubbing it with a fur) the conductor will be attracted to the ruler. When dc current flows in the wire , no matter in what direction nothing its changing , the wire still remains attracted to the plastic ruler. When a permanent magnet is approach to the conductor while life the conductor will be attracted or repulsed depending on the current direction (obviously). I thought that the electrons on the ruler will be at half of the speed relative to those moving in the wire , so there will be two electron flows in opposite direction which will lead to a repulsive magnetic force between the ruler and the conductor! What do I'm missing (if I'm missing something)?

(this is a double post because i don't really know where should belong ...sorry)
 
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The electrons on the ruler are stationary. There is no current in a plastic ruler-it is an insulator.
Bob S
 
Bob S said:
The electrons on the ruler are stationary. There is no current in a plastic ruler-it is an insulator.
Bob S

that's the point! If an electric field in one frame of reference is a magnetic force in another dynamic frame, than the electrons in the wire would be influenced by the magnetic field of the stationary electrons on the surface of the ruler, which are traveling at half of the speed relative to those in the wire...so the stationary electrons are seen as moving by the electrons in the conductor, so were is the repulsive magnetic force? The experiment is simple you can do it in 10 minutes...
 
Relative to the electrons in the wire, the ruler electrons would be moving at full speed, not half speed. Anyhow, there's no magnetic force because the wire is neutral overall.
 
The attractive force between the ruler and conductor is electrostatic: the negative charge on the ruler induces a positive charge on the side of the conductor closest to it and a negative charge on the side furthest away from it. This happens because of Gauss's law and its application to perfect conductors. This force is not influenced by magnetic fields (since all the charges are stationary) or by currents in the wire (that electric field is perpendicular to the one caused by the static charge).

Also, if you want to consider the electrons in the ruler moving at half the speed of those in the wire then you also have to work out the relative velocity of the permenant magnet with respect to this frame of reference.
 
In our frame of reference, a current would be influenced by the charge on the ruler by using the first half of the Lorentz force equation:

F = q(E + v x B) = qE + I x B

which is just the force on a particle of charge q in an electrostatic field E.

You can Lorentz-transform this into any other frame, including one where the charges in the wire are static.

Bob S
 
pseudophonist said:
The attractive force between the ruler and conductor is electrostatic: the negative charge on the ruler induces a positive charge on the side of the conductor closest to it and a negative charge on the side furthest away from it. This happens because of Gauss's law and its application to perfect conductors. This force is not influenced by magnetic fields (since all the charges are stationary) or by currents in the wire (that electric field is perpendicular to the one caused by the static charge).

Also, if you want to consider the electrons in the ruler moving at half the speed of those in the wire then you also have to work out the relative velocity of the permenant magnet with respect to this frame of reference.

The magnet is there just for fun it has noting to do with the experiment, was on my desk and i checked if the current really flows (i have some bad alligator clips that's it...i do have a ammeter...just because)
The attraction to the charged plastic ruler of course is electrostatic,...
And yes they move at the same speed relative to those in the copper wire...(my mistake...I'm not perfect...yet :)
And yes the wire is neutral (over all) but so are two conductors carrying current and they still have a magnetic interaction between them...

- What would have been your opinion if i would say that when the current flows, the conductor is repealed of the ruler?
 
Last edited:
crx said:
- What would have been your opinion if i would say that when the current flows, the conductor is repealed of the ruler?
If the wire had capacitance C per unit length and voltage V with respect to another conductor, it would have charge Q=CV per unit length. In this case, this wire would either attract or repel the ruler.
Bob S
 

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