Finding Current and B Field given J(p) in Z Direction

AI Thread Summary
The discussion revolves around calculating the total current flowing through a wire given a specific current density function, J(p) = (I/pi) * p^2 * e^(-p^2), and finding the magnetic field. Participants emphasize the need to integrate the current density correctly in cylindrical coordinates, specifically suggesting that the integration limits should extend from 0 to infinity rather than an arbitrary distance. One user expresses difficulty in proving the total current equals 'I' and shares their integration attempts, which led to an incorrect result. Clarifications are made regarding a typo in the exponential term, confirming that it should be p^2 instead of x^2. The conversation highlights the importance of proper integration techniques and limits in solving the problem accurately.
iontail
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Homework Statement



the current density is given by J(p) = (I/pi) * p^2 * e^(-p^2) in z direction
The question is to first show that the cureent flowing through the wire is 'I' and then to find then to find the B field.

Homework Equations



stokes theorem.
integral of B.dl = I

I = J.dS

The Attempt at a Solution



i can find the magnetic field. however i am stuck on the first part that requires me to proof the total current is I.
I set up the problem in cylindrical coordinates and tired the double integration between 0 to 2pi and o to a(arbitsry distance) however this does not give the correct result. plese point me in the right direction
 
Last edited:
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Hi iontail,

iontail said:

Homework Statement



the current density is given by J(p) = (I/pi) * p^2 * e^(-x^2) in z direction
The question is to first show that the cureent flowing through the wire is 'I' and then to find then to find the B field.

Homework Equations



stokes theorem.
integral of B.dl = I

I = J.dS

The Attempt at a Solution



i can find the magnetic field. however i am stuck on the first part that requires me to proof the total current is I.
I set up the problem in cylindrical coordinates and tired the double integration between 0 to 2pi and o to a(arbitsry distance) however this does not give the correct result. plese point me in the right direction

Can you verify your equation? You have:

J(p) = (I/pi) * p^2 * e^(-x^2)

Is that supposed to be p^2 in the exponential instead of x^2? Also, can you show your work for the integration?
 
sorry about that it is supposed to b p^2, a typo. I tried integrating by parts on the ,p, terms and using the cylindrical coordinates formula for for dS. I get e^-p(p+3) as result
 
i updated the question as well
 
iontail said:
sorry about that it is supposed to b p^2, a typo. I tried integrating by parts on the ,p, terms and using the cylindrical coordinates formula for for dS. I get e^-p(p+3) as result

I don't believe the integral should be cut off at an arbitrary limit (like you are doing with the quantity a); instead the radial varible p should be integrated from 0 to infinity. If you are still getting the wrong answer, please post the integration steps you are taking.
 

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