Magnetic Flux Through Wire Loop

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Homework Help Overview

The problem involves calculating the magnetic flux through a wire loop with a specified radius, positioned at a certain distance from a long straight wire carrying a current. The context is rooted in electromagnetism, specifically focusing on magnetic fields and flux calculations.

Discussion Character

  • Exploratory, Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • The original poster attempts to combine equations related to magnetic fields and flux to solve the problem. Some participants discuss the scenario where the wire is in the same plane as the loop and explore the magnetic field expression used. Others question the derivation of the magnetic field formula and its application in the context of the problem.

Discussion Status

The discussion is ongoing, with participants sharing their interpretations and mathematical expressions. There is an exchange of ideas regarding the magnetic field's derivation and its implications for calculating flux, but no consensus has been reached yet.

Contextual Notes

Participants are navigating the complexities of the problem, including the assumptions about the relative positions of the wire and the loop, and the mathematical challenges involved in integrating the magnetic field over the loop's area.

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Homework Statement


A wire loop with radius R is located a distance d from a long straight wire carrying a current I. Find the flux through the loop.

Homework Equations


B = \muI/(4\pi)
Magnetic Field above wire
\phi=B*da*cos\vartheta

The Attempt at a Solution


Somehow you have to combine the two equations to find the flux through the circular loop. Any help would be greatly appreciated as I am stumped.
 
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I don't know whether I have understood rhe problem, but I have worked out the situation in which the wire is on the same plane of the circle (in general I think that the computation is conceptually easy but hard in the practice).

In this case, the magnetic field generated by the wire at distance r is

B(r)=\frac{2I}{cr}

in cgs units.


so, if we assume that d>R>0, we have that the flux \Phi is


\Phi=\int_{d-R}^{d+R}dr\frac{2I}{cr}2\sqrt{R^2-(d-r)^2}
 
Yes you are right that the wire loop is in the same plane as the wire. Care to explain the formula you used for the magnetic field generated by the wire?
 
Yes: from the 4-th Maxwell's equation (ignoring the electric field: the problem is a magnetostatic problem):

\nabla \times \vec{B}=\frac{4\pi}{c}\vec{J}


Integrate over a surface S; transform the integral of the rotor in a line integral through one of the usual theorem (Green's theorem, maybe, but I'm not sure); moreover the integral of J gives the current and you find the relation.
 

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