(C) The current $i$ produced by a charge $q$ moving in a circle with frequency $n$ is given by $i = q \times n$.The magnetic field $B$ at the centre o

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$\frac{2\pi nq}{r} \times 10^{-7} \text{ N/A} \cdot \text{m}$

(C) The current $i$ produced by a charge $q$ moving in a circle with frequency $n$ is given by $i = q \times n$.The magnetic field $B$ at the centre of a circular loop is given by the formula $B = \frac{\mu_0 i}{2r}$.Substituting $\frac{\mu_0}{4\pi} = 10^{-7} \text{ T} \cdot \text{m/A}$, we get $\frac{\mu_0}{2} = 2\pi \times 10^{-7}$.Thus, $B = (2\pi \times 10^{-7}) \times \frac{i}{r}$.Substituting $i = nq$, we get $B = \frac{2\pi nq}{r} \times 10^{-7} \text{ N/A} \cdot \text{m}$.

Class 12 Physics Moving Charges and Magnetism Biot-Savart's Law and its application

Medium

$A$ charge $q$ $C$ moves in a circle at $n$ revolutions per second and the radius of the circle is $r$ $m$. The magnetic field at the centre of the circle is:

A
$\frac{2\pi q}{nr} \times 10^{-7} \text{ N/A} \cdot \text{m}$
B
$\frac{2\pi q}{r} \times 10^{-7} \text{ N/A} \cdot \text{m}$
C
$\frac{2\pi nq}{r} \times 10^{-7} \text{ N/A} \cdot \text{m}$
D
$\frac{2\pi q}{r} \text{ N/A} \cdot \text{m}$

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Moving Charges and Magnetism

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Biot-Savart's Law and its application

$A$ circular coil carrying current has radius $R$. The distance from the centre of the coil on the axis where the magnetic induction will be $\frac{1}{27}$th of its value at the centre of the coil is:

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An infinite number of straight wires,each carrying current $I$,are equally placed as shown in the figure. Adjacent wires have current in opposite directions. The net magnetic field at point $P$ is:

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$N$ equally spaced charges,each of value $q$,are placed on a circle of radius $R$. The circle rotates about its axis with an angular velocity $\omega$ as shown in the figure. $A$ bigger Amperian loop $B$ encloses the whole circle,whereas a smaller Amperian loop $A$ encloses a small segment. The difference between enclosed currents,$I_A - I_B$,for the given Amperian loops is

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Surface charge density on a ring of radius $a$ and width $d$ is $\sigma$ as shown in the figure. It rotates with frequency $f$ about its own axis. Assume that the charge is only on the outer surface. The magnetic field induction at the centre is (Assume that $d \ll a$):

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$A$ charge $q$ $C$ moves in a circle at $n$ revolutions per second and the radius of the circle is $r$ $m$. The magnetic field at the centre of the circle is:

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$A$ circular coil carrying current has radius $R$. The distance from the centre of the coil on the axis where the magnetic induction will be $\frac{1}{27}$th of its value at the centre of the coil is:

Consider a tightly wound $100$ turn coil of radius $10 \; cm$,carrying a current of $1 \; A$. What is the magnitude of the magnetic field at the centre of the coil?

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Surface charge density on a ring of radius $a$ and width $d$ is $\sigma$ as shown in the figure. It rotates with frequency $f$ about its own axis. Assume that the charge is only on the outer surface. The magnetic field induction at the centre is (Assume that $d \ll a$):

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