(A) Using Ampere's circuital law,$\oint \vec{B} \cdot d\vec{l} = \mu_0 I_{\text{enclosed}}$.Case $(i)$: For $x < a$,the current enclosed by an Amperia

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(A) Using Ampere's circuital law,$\oint \vec{B} \cdot d\vec{l} = \mu_0 I_{\text{enclosed}}$.Case $(i)$: For $x Applying Ampere's law: $B_1 (2 \pi x) = \mu_0 i_o \frac{x^2}{a^2} \implies B_1 = \frac{\mu_0 i_o x}{2 \pi a^2}$.Case $(ii)$: For $a Applying Ampere's law: $B_2 (2 \pi x) = \mu_0 i_o \implies B_2 = \frac{\mu_0 i_o}{2 \pi x}$.The ratio of the magnetic fields is $\frac{B_1}{B_2} = \frac{\frac{\mu_0 i_o x}{2 \pi a^2}}{\frac{\mu_0 i_o}{2 \pi x}} = \frac{x}{a^2} \cdot x = \frac{x^2}{a^2}$.

Class 12 Physics Moving Charges and Magnetism Ampere’s circuital law and its application (Solenoid and Toroid)

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$A$ coaxial cable consists of an inner wire of radius $a$ surrounded by an outer shell of inner and outer radii $b$ and $c$ respectively. The inner wire carries an electric current $i_o$,which is distributed uniformly across its cross-sectional area. The outer shell carries an equal current in the opposite direction,also distributed uniformly. What will be the ratio of the magnetic field at a distance $x$ from the axis when $(i)$ $x < a$ and $(ii)$ $a < x < b$?

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A
$\frac{x^2}{a^2}$
B
$\frac{a^2}{x^2}$
C
$\frac{x^2}{b^2 - a^2}$
D
$\frac{b^2 - a^2}{x^2}$

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Class 12

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Moving Charges and Magnetism

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Ampere’s circuital law and its application (Solenoid and Toroid)

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$A$ solenoid is $1.5 \, m$ long and its inner diameter is $4.0 \, cm$. It has three layers of windings of $1000$ turns each and carries a current of $2.0 \, A$. The magnetic flux for a cross-section of the solenoid is nearly:

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There are $50$ turns of a wire in every $1$ $cm$ length of a long solenoid. If $4$ $A$ current is flowing in the solenoid,the approximate value of the magnetic field along its axis at an internal point and at one end will be respectively:

Medium

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Explain Ampere's circuital law.

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What is the magnetic field at point $P$ located at a distance of $\frac{3R}{2}$ from the center of the cylindrical conductor with inner radius $R$ and outer radius $2R$ carrying a current $i$?

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$A$ coaxial cable having radii $a, b$ and $c$ carries equal and opposite currents of magnitude $i$ in the inner and outer conductors. What is the magnitude of the magnetic induction at point $P$ outside of the cable at a distance $r$ from the axis?

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$A$ solenoid is $1.5 \, m$ long and its inner diameter is $4.0 \, cm$. It has three layers of windings of $1000$ turns each and carries a current of $2.0 \, A$. The magnetic flux for a cross-section of the solenoid is nearly:

There are $50$ turns of a wire in every $1$ $cm$ length of a long solenoid. If $4$ $A$ current is flowing in the solenoid,the approximate value of the magnetic field along its axis at an internal point and at one end will be respectively:

Explain Ampere's circuital law.

What is the magnetic field at point $P$ located at a distance of $\frac{3R}{2}$ from the center of the cylindrical conductor with inner radius $R$ and outer radius $2R$ carrying a current $i$?

$A$ coaxial cable having radii $a, b$ and $c$ carries equal and opposite currents of magnitude $i$ in the inner and outer conductors. What is the magnitude of the magnetic induction at point $P$ outside of the cable at a distance $r$ from the axis?

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