Question:
Two parallel conductors carry current in opposite directions as shown in figure. One conductor carries a current of $10.0\, A$. Point $C$ is a distance $\frac{d}{2}$ to the right of the $10.0\, A$ current. If $d =18\, cm$ and $I$ is adjusted so that the magnetic field at $C$ is zero, the value of the current $I$ is
Two parallel conductors carry current in opposite directions as shown in figure. One conductor carries a current of $10.0\, A$. Point $C$ is a distance $\frac{d}{2}$ to the right of the $10.0\, A$ current. If $d =18\, cm$ and $I$ is adjusted so that the magnetic field at $C$ is zero, the value of the current $I$ is
Updated On: Jan 30, 2025
- 10.0 A
- 30.0A
- 8.0A
- 18.0A
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The Correct Option is B
Solution and Explanation
The magnetic field at $C$ due to first conductor is
$B_{1}=\frac{\mu_{0}}{2 \pi} \frac{I}{3 d/2}$
(since, point $C$ is separated by
$d +\frac{d}{2}=\frac{3 d}{2}$ from 1st conductor).
The direction of field is perpendicular to the plane of paper and directed outwards.
The magnetic field at $C$ due to second conductor is
$=B_{2}=\frac{\mu_{0}}{2 \pi} \frac{10}{d /2}$
(since, point $C$ is separated by
$\frac{d}{2}$ from 2 nd conductor)
The direction of field is perpendicular to the plane of paper and directed inwards. Since, direction of $B_{1}$ and $B_{2}$ at point $C$ is in opposite direction and the magnetic field at $C$ is zero, therefore,
$B_{1}=B_{2} \frac{\mu_{0}}{2 \pi} \frac{I}{3 d/2}=\frac{\mu_{0}}{2 \pi} \frac{10}{d/ 2}$
On solving $I=30.0\, A$
$B_{1}=\frac{\mu_{0}}{2 \pi} \frac{I}{3 d/2}$
(since, point $C$ is separated by
$d +\frac{d}{2}=\frac{3 d}{2}$ from 1st conductor).
The direction of field is perpendicular to the plane of paper and directed outwards.
The magnetic field at $C$ due to second conductor is
$=B_{2}=\frac{\mu_{0}}{2 \pi} \frac{10}{d /2}$
(since, point $C$ is separated by
$\frac{d}{2}$ from 2 nd conductor)
The direction of field is perpendicular to the plane of paper and directed inwards. Since, direction of $B_{1}$ and $B_{2}$ at point $C$ is in opposite direction and the magnetic field at $C$ is zero, therefore,
$B_{1}=B_{2} \frac{\mu_{0}}{2 \pi} \frac{I}{3 d/2}=\frac{\mu_{0}}{2 \pi} \frac{10}{d/ 2}$
On solving $I=30.0\, A$
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Concepts Used:
Magnetic Field
The magnetic field is a field created by moving electric charges. It is a force field that exerts a force on materials such as iron when they are placed in its vicinity. Magnetic fields do not require a medium to propagate; they can even propagate in a vacuum. Magnetic field also referred to as a vector field, describes the magnetic influence on moving electric charges, magnetic materials, and electric currents.
A magnetic field can be presented in two ways.
- Magnetic Field Vector: The magnetic field is described mathematically as a vector field. This vector field can be plotted directly as a set of many vectors drawn on a grid. Each vector points in the direction that a compass would point and has length dependent on the strength of the magnetic force.
- Magnetic Field Lines: An alternative way to represent the information contained within a vector field is with the use of field lines. Here we dispense with the grid pattern and connect the vectors with smooth lines.
Properties of Magnetic Field Lines
- Magnetic field lines never cross each other
- The density of the field lines indicates the strength of the field
- Magnetic field lines always make closed-loops
- Magnetic field lines always emerge or start from the north pole and terminate at the south pole.