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Question
Using Biot-Savart law, deduce the expression for the magnetic field at a point (x) on the axis of a circular current carrying loop of radius R. How is the direction of the magnetic field determined at this point?
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Solution
Magnetic field on the axis of a circular current loop
I = Current in the loop
R = Radius of the loop
X-axis = Axis of the loop
X = Distance between O and P
dl = Conducting element of the loop
According to the Biot–Savart law, the magnetic field at P is
`dB =(μ_0 I | dl xxr)/(4π r^3)`
r2 = x2 + R2
|dl × r| = rdl (Because they are perpendicular)
`dB =(μ_0 I dl )/(4π (x^2 + R^2))`
dB has two components: dBx and dB⊥. dB⊥ is cancelled out and only the x-component remains.
∴ dBx= dBcos θ
`cos θ= R/ (x^2 + R^2)^(3/2) hati`
Summation of dl over the loop is given by 2πR.
∴ `B = B= B_x hati = (μ_0 I R^2)/(2(x^2 + R^2)^(3/2)) hati `
The direction of
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