Magnetic Field Strength at a Point Along an Infinite Wire

AI Thread Summary
The discussion centers on calculating the magnetic field at a point (0, L) due to an infinite wire carrying current I. The key equation used is B = μ₀I/(2πR), where R is the distance from the wire to the point of interest. The confusion arises from the professor's solution indicating that B' = 1/2 B, suggesting that only half of the wire's contribution to the magnetic field is considered. Participants speculate that this may be due to the wire being conceptualized as extending from negative to positive infinity, thus only accounting for one side. The lack of a diagram and the non-physical nature of the problem are noted as potential issues.
frostking
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Homework Statement


A current I flows to the right on the x-axis from the origin to x = infinity. What's the magnitude of the magnetic field at (x,y) = (0,L)?


Homework Equations


B = u sub 0 time I/(2 pi R)


The Attempt at a Solution



We use above equation since we have an extremely long wire. I would think I should just replace the R for the L as the given point value of y. However, this is an old exam question and the professor's solution states that B ' = 1/2 B and therefore the answer is:

u sub 0 times I / (4pi L) Could someone please explain why the statement of B' = 1/2 B makes sense. If I know that then of course the answer in the exam key would make perfect sense! Thanks for your time and effort, Frostking
 
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frostking said:

Homework Statement


A current I flows to the right on the x-axis from the origin to x = infinity. What's the magnitude of the magnetic field at (x,y) = (0,L)?


Homework Equations


B = u sub 0 time I/(2 pi R)


The Attempt at a Solution



We use above equation since we have an extremely long wire. I would think I should just replace the R for the L as the given point value of y. However, this is an old exam question and the professor's solution states that B ' = 1/2 B and therefore the answer is:

u sub 0 times I / (4pi L) Could someone please explain why the statement of B' = 1/2 B makes sense. If I know that then of course the answer in the exam key would make perfect sense! Thanks for your time and effort, Frostking

The only thing I can think of is the strange statement that the current flows "right on the x-axis from the origin to x = infinity". How does the current return from infinity to the origin? It can't just magically appear at the origin and flow away. Is there a diagram associated with the problem?
 
There is no diagram and no explanation of this magical B' that he comes up with. The only thing I can figure is that the wire goes from negative infinity to positive infinity and therefore we are only considering 1/2 of the total. What do you think of that? Thanks for your time! Frostking
 
frostking said:
There is no diagram and no explanation of this magical B' that he comes up with. The only thing I can figure is that the wire goes from negative infinity to positive infinity and therefore we are only considering 1/2 of the total. What do you think of that? Thanks for your time! Frostking

Yeah, that seems to be what is being asked, but the non-physical nature of the question is problematic. Maybe try different ways of routing the current back to the origin, to see if you can cancel out the x-component of the B-field that would result from only counting the current from the origin to infinity... ?
 
Thanks for your input. I hope the test tomorrow night has more concrete questions! Frostking
 
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