Magnetic Force on a Current Carrying Wire

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SUMMARY

The discussion centers on determining the direction of the magnetic field (B) acting on a current-carrying wire (i) in a uniform magnetic field, specifically when the force is maximized. The correct application of the right-hand rule reveals that if the current is directed in the positive y-direction, the magnetic field must be oriented in the negative y-direction to achieve maximum force. This conclusion is supported by the understanding that the force is perpendicular to both the current and the magnetic field, confirming that the magnetic field direction is indeed -y.

PREREQUISITES
  • Understanding of the right-hand rule in electromagnetism
  • Familiarity with the concepts of magnetic force on a current-carrying conductor
  • Knowledge of vector orientation in three-dimensional space
  • Basic principles of uniform magnetic fields
NEXT STEPS
  • Study the right-hand rule in detail to apply it correctly in various scenarios
  • Explore the mathematical formulation of the magnetic force on a wire using F = i(L × B)
  • Investigate the effects of varying angles between current and magnetic field on force magnitude
  • Learn about applications of magnetic fields in electrical engineering and physics
USEFUL FOR

Students of physics, electrical engineers, and educators looking to deepen their understanding of electromagnetism and the behavior of current-carrying conductors in magnetic fields.

taliaroma
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The figure shows a current i through a wire in a uniform magnetic field , as well as the magnetic force acting on the wire. The field is oriented so that the force is maximum. In what direction is the field?

I have uploaded the figure, and the relevant equations.

My reasoning:
-L is in the direction of i.
-Assume i is a positive value.
Therefore, B is in the direction of +y.

However, the key says the answer is -y.

Why is that?
 

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You're doing the right hand rule incorrectly. Your thumb needs to be pointing in the direction of the magnetic force. When you do this and orient your fingers to point in the direction of i in the picture, you will see that they curl down, in the -y direction.
 
taliaroma said:
The figure shows a current i through a wire in a uniform magnetic field , as well as the magnetic force acting on the wire. The field is oriented so that the force is maximum. In what direction is the field?

I have uploaded the figure, and the relevant equations.

My reasoning:
-L is in the direction of i.
-Assume i is a positive value.
Therefore, B is in the direction of +y.

However, the key says the answer is -y.

Why is that?

Homework Statement

Homework Equations


The Attempt at a Solution


Think about it this way:

What has to be the orientation of L and B in order for the force to be the maximum? What does theta have to be? I am assuming you understand that it is perpendicular since you narrowed it down to the y direction. Now you have two choices, either the + y direction or the - y direction. Assuming you have a positive charge and the force is out of the page in z direction (thumb points out of the page, fingers point in direction of current towards left, -x direction, now which way do your fingers naturally naturally curl?). This is the direction of the magnetic field (assuming its not changing and is uniform). Does that make sense?
 
sona1177 said:
Think about it this way:

What has to be the orientation of L and B in order for the force to be the maximum? What does theta have to be? I am assuming you understand that it is perpendicular since you narrowed it down to the y direction. Now you have two choices, either the + y direction or the - y direction. Assuming you have a positive charge and the force is out of the page in z direction (thumb points out of the page, fingers point in direction of current towards left, -x direction, now which way do your fingers naturally naturally curl?). This is the direction of the magnetic field (assuming its not changing and is uniform). Does that make sense?

Yes, that's very helpful. Thank you!
 

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