Triangular loop in magnetic field

AI Thread Summary
A right-triangular current loop with a hypotenuse of 5 cm and a current of 0.42 A is placed in a uniform magnetic field of 0.3 T. The magnetic force on side AB has been calculated as -0.0063 N, with the negative sign indicating the force direction according to the right-hand rule. The discussion emphasizes the importance of correctly applying the right-hand rule to determine the direction of forces on sides BC and CA, which also need to be calculated similarly. Participants clarify that the angle between the current and magnetic field is 90 degrees, affecting the force's magnitude but not its direction. The conversation highlights the need for proper vector cross-product understanding to solve for the forces on all sides of the loop.
Juntao
Messages
45
Reaction score
0
Sup all. I need help setting this problem up.

A right-triangular current loop has two 45° angles and a hypotenuse a = 5 cm. The loop lies in the x-y plane, with its hypotenuse parallel to the y-axis. A net current I = 0.42 A circulates in the loop in the direction shown in the figure. A spatially uniform magnetic field B = 0.3 T points in the +x direction. The +z direction is OUT of the screen.

Calculate:
1) F_Z (AB)=?
2) F_Z (BC)=?
3) F_Z (CA)=?

Where F_Z is the magnetic force in the Z direction on side AB, BC, or CA.

Now, I know that Force_B = iLxB
where L is length of side
and B is the magnetic field.

Obviously, I have to do some cross product action here.
I know so far that the answer for 1) is (.42A)(.05m)(.3T) sin theta=-.0063N.
Now, I'm not sure why that is the answer. Is it because the angle is 270 degrees, and that's why the answer is negative?

I'm stuck on the last two. I do know that the answer for 3 is either going to be the same as 2, or equal in magnitude but opposite in sign is my guess.

Any help greatly appreciated.
 

Attachments

  • triangle.gif
    triangle.gif
    1.1 KB · Views: 1,003
Last edited:
Physics news on Phys.org
Juntao said:
Now, I know that Force_B = iLxB
where L is length of side
and B is the magnetic field.
Right.
I know so far that the answer for 1) is (.42A)(.05m)(.3T) sin theta=-2.52N.
Now, I'm not sure why that is the answer. Is it because the angle is 270 degrees, and that's why the answer is negative?
What makes you think that is the answer? What's the angle θ? What's the sine of that angle? (Did you check the arithmetic?) Use the right hand rule to find the direction of the force (the direction of the cross-product). Does it point in the positive or negative z direction?
 
Ok, I figured out why its negative. Right hand rule shows me the angle between the magnetic field and the current is -90 degrees. Also, I know that's the RIGHT answer because the computer told me so. Sorry if I did not indicate that earlier. So how do I setup these last two parts? Do I have to create vectors and cross them?
 
Juntao said:
Ok, I figured out why its negative. Right hand rule shows me the angle between the magnetic field and the current is -90 degrees. Also, I know that's the RIGHT answer because the computer told me so.
I don't think you're quite done with the first problem yet. :smile: (And all three are solved in exactly the same manner anyway.) Some comments for #1:

(a) Use the right hand rule to find the direction of the force, not the angle between the magnetic field and the current. The right hand rule tells me that the force points into the page, thus along the negative z-axis. That's why it's negative.

(b) The angle between the magnetic field and the current is simply 90 degrees. (But it doesn't matter whether you call it 90, -90, or 270.) Use F = iLBsinθ to find the magnitude of the force. (The direction is given by the right hand rule.)

(c) Regardless of what the computer says, do you think that (.42A)(.05m)(.3T) sin 90 = 2.52N ?? :rolleyes:
 
My bad, I computed the answer wrong. Now I feel like an idiot. Supposed to be -.0063N, not 2.52N. :(


Okay, now is part 2 and 3 done the same way? Sorry, but I suck at using the right hand rule. I know that I curl my fingers in the direction of the magnetic field, but sometimes I don't get it right. Now when the current is traveling down BC, right hand rule tells me the direction of the force points diagonally to the right? Likewise, right hand rule tells me the direction of the force along side AC is down to the left?

Am I even remotely close?
 
learn the right hand rule!

Juntao said:
I know that I curl my fingers in the direction of the magnetic field, but sometimes I don't get it right.
One version of the right-hand rule (the one I use) is to curl your fingers as if rotating the first vector (iL) into the second (B): then your thumb will point in the direction of the force. Remember that any cross-product of two vectors is always perpendicular to both vectors.

This may help: http://www.physics.brocku.ca/faculty/sternin/120/slides/rh-rule.html
Now when the current is traveling down BC, right hand rule tells me the direction of the force points diagonally to the right? Likewise, right hand rule tells me the direction of the force along side AC is down to the left?
No! Since iL and B are in the x-y plane, the magnetic force must be perpendicular to that plane: that means along the z-axis. Use the right hand rule to find out if it's pointing towards + z or - z. (Didn't you wonder why you are asked for the z-components of the force?)
 
Last edited by a moderator:

Thread 'Rolling without slipping on a curved surface'

Kindly see the attached pdf. My attempt to solve it, is in it. I'm wondering if my solution is right. My idea is this: At any point of time, the ball may be assumed to be at an incline which is at an angle of θ(kindly see both the pics in the pdf file). The value of θ will continuously change and so will the value of friction. I'm not able to figure out, why my solution is wrong, if it is wrong .
View full post »

Thread 'Struggling to understand the concept of this question (ice cube in water optics question)'

TL;DR Summary: I came across this question from a Sri Lankan A-level textbook. Question - An ice cube with a length of 10 cm is immersed in water at 0 °C. An observer observes the ice cube from the water, and it seems to be 7.75 cm long. If the refractive index of water is 4/3, find the height of the ice cube immersed in the water. I could not understand how the apparent height of the ice cube in the water depends on the height of the ice cube immersed in the water. Does anyone have an...
View full post »
Thread 'A bead-mass oscillatory system problem'

Thread 'A bead-mass oscillatory system problem'

I can't figure out how to find the velocity of the particle at 37 degrees. Basically the bead moves with velocity towards right let's call it v1. The particle moves with some velocity v2. In frame of the bead, the particle is performing circular motion. So v of particle wrt bead would be perpendicular to the string. But how would I find the velocity of particle in ground frame? I tried using vectors to figure it out and the angle is coming out to be extremely long. One equation is by work...
View full post »

Similar threads

Induced current and force on circular loop in varying magnetic field
Replies
4
Views
1K
What is the net force on the current loop?
Replies
8
Views
2K
Understanding Torque in a Magnetic Field with Loop
Replies
37
Views
4K
Can the Magnetic Field Be Determined Using Biot-Savart Law Superposition?
Replies
2
Views
960
Derivation Of Torque On Current Loop Due To Uniform Magnetic Field
Replies
4
Views
2K
Direction and magnitude of electric field produced by current change
Replies
8
Views
1K
How to obtain correct negative sign in calculation of motional emf?
Replies
2
Views
922
Direction of the magnetic needle
Replies
11
Views
2K
How Does Induced Current Change with Loop Acceleration Through a Magnetic Field?
Replies
8
Views
1K
Induced Current Direction in a Changing Magnetic Field
Replies
1
Views
2K

Hot Threads

Recent Insights

Back
Top