How Does Current Direction Affect Magnetic Force on a Conductor?

In summary: In determining the direction and the angle the magnetic force on teh wire makes with the y-axis (north), i should be applying the right hand rule to the vectors of the current and magnetic field.
  • #1
ACLerok
194
0
magnetic forces on a conductor

A straight, vertical wire carries a current of 1.13A downward in a region between the poles of a large superconducting electromagnet, where the magnetic field has a magnitude of 0.553T and is horizontal.

What is the magnitude of the magnetic force on a section of the wire with a length of 1.00cmthat is in this uniform magnetic field, if the magnetic field direction is 29.0degrees south of west?

i read the textbook and tried using F= current*length*magnetic field*sin(theta) and i got .00303 N.. is this correct or am i going about this all wrong?
 
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  • #2
ACLerok said:
i read the textbook and tried using F= current*length*magnetic field*sin(theta) and i got .00303 N.. is this correct or am i going about this all wrong?
In that formula, theta is the angle between the current in the wire and the magnetic field. In this problem the wire is vertical (call it along the z-axis) and the magnetic field is horizontal (somewhere in the x-y plane). So what is the angle between them?
 
  • #3
i just tried taking the cross product of I and B but that didnt work out right? how wold i find the angle between the magnetic field and the current?
 
  • #4
The cross product would work fine if you used the correct angle between the vectors. Hint: the wire is vertical and the field is horizontal. :smile:
 
  • #5
would that angle just be the one given then?
 
  • #6
angle between vertical and horizontal = ?

ACLerok said:
would that angle just be the one given then?
If by that you mean "29.0 degrees", then no. That's the angle the field makes with west, not the angle it makes with the wire.

The way I'm picturing this coordinate system is: the wire is along the z-axis, north is along the y-axis, and east is along the x-axis. Specifying the angle that the field makes with west (the -x axis) doesn't change the fact that the field is horizontal and thus perpendicular to the wire.
 
  • #7
help please!
 
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  • #8
Anyone help this homework problem
 
  • #9
Did you read my response? Do you know what perpendicular means?
 
  • #10
so that angle is 90 degrees? if so, what does the 29 have to do with anything?
 
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  • #11
ACLerok said:
so that angle is 90 degrees?
Yes.
if so, what does the 29 have to do with anything?
You'd need that to find the direction of the magnetic force.
 
  • #12
Doc Al said:
Yes.
You'd need that to find the direction of the magnetic force.

i guess now I'm trying to find the angle the magnetic force will make relative to some axis, say north. time to use the right hand rule correct?
 
  • #13
Yes, use the right hand rule.
 
  • #14
Doc Al said:
Yes, use the right hand rule.

in determining the direction and the angle the magnetic force on teh wire makes with the y-axis (north), i should be applying the right hand rule to the vectors of the current and magnetic field correct?
 
  • #15
That is correct.
 

FAQ: How Does Current Direction Affect Magnetic Force on a Conductor?

What is a vector?

A vector is a mathematical quantity that has both magnitude and direction. It is typically represented by an arrow pointing in the direction of the vector with a length proportional to its magnitude.

How does a magnetic field impact a moving charged particle?

A magnetic field exerts a force on a moving charged particle, causing it to experience a change in direction perpendicular to both the magnetic field and the particle's velocity. This is known as the Lorentz force.

What is the right-hand rule in relation to magnetic fields?

The right-hand rule is a tool used to determine the direction of the magnetic force on a moving charged particle. It states that if you point your right thumb in the direction of the particle's velocity and your fingers in the direction of the magnetic field, then your palm will face the direction of the magnetic force.

How do you calculate the magnitude of the magnetic force on a moving charged particle?

The magnitude of the magnetic force on a moving charged particle can be calculated using the equation: F = qvBsinθ, where q is the charge of the particle, v is its velocity, B is the magnetic field strength, and θ is the angle between the particle's velocity and the magnetic field.

What are some real-life applications of magnetic force?

Magnetic force has many practical applications, including in electric motors, generators, MRI machines, and particle accelerators. It is also used in magnetic levitation trains, magnetic compasses, and magnetic separation processes in industries such as mining and recycling.

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