Consider a circular loop of radius R on the xy-plane carrying a steady current anticlockwise. The magnetic field at the center of the loop is given by
- $\frac{\mu_0}{2R}i \hat{x}$
- $\frac{\mu_0}{2R} i \hat{y}$
- $\frac{\mu_0}{2R} i \hat{z}$
- $\frac{\mu_0}{R} i \hat{x}$
The Correct Option is C
Solution and Explanation
From Biot-savart law, the magnetic field at some point in space at distance R is given as,
$d B=\frac{\mu_{0}}{4 \pi} i \frac{ d l \times P }{R^{3}}$
Since, the loop is circular in shape so,
$=2 \pi R$
Now integrating the field in whole length of wire loop
$\Rightarrow \int_\limits{0}^{B} d B=\frac{\mu_{0}}{4 \pi} \frac{i R}{R^{3}} \int_\limits{0}^{2 \pi R} d l $
$\Rightarrow B=\frac{\mu_{0}}{4 \pi} \frac{i}{R^{2}} 2 \pi R=\frac{\mu_{0} i}{2 R}$
Also, with help of right hand thumb rule, we can conclude, that the magnetic field is in $+ z$ direction.
$\Rightarrow B =\frac{\mu_{0} i}{2 R} \hat{ z }$
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Concepts Used:
Moving Charges and Magnetism
Moving charges generate an electric field and the rate of flow of charge is known as current. This is the basic concept in Electrostatics. Another important concept related to moving electric charges is the magnetic effect of current. Magnetism is caused by the current.
Magnetism:
- The relationship between a Moving Charge and Magnetism is that Magnetism is produced by the movement of charges.
- And Magnetism is a property that is displayed by Magnets and produced by moving charges, which results in objects being attracted or pushed away.
Magnetic Field:
Region in space around a magnet where the Magnet has its Magnetic effect is called the Magnetic field of the Magnet. Let us suppose that there is a point charge q (moving with a velocity v and, located at r at a given time t) in presence of both the electric field E (r) and the magnetic field B (r). The force on an electric charge q due to both of them can be written as,
F = q [ E (r) + v × B (r)] ≡ EElectric +Fmagnetic
This force was based on the extensive experiments of Ampere and others. It is called the Lorentz force.