Advertisements
Advertisements
प्रश्न
Figure shows a long wire bent at the middle to form a right angle. Show that the magnitudes of the magnetic fields at the point P, Q, R and S are equal and find this magnitude.
उत्तर
As shown in the figure, points P, Q, R and S lie on a circle of radius d.
Let the wires be named W1 and W2.
Now,
At point P, the magnetic field due to wire W1 is given by
B1 = 0
At point P, the magnetic field due to wire W2 is given by
\[B_2 = \frac{\mu_0 i}{4\pi d}\] (Perpendicular to the plane in outward direction)
\[\Rightarrow B_{net} = \frac{\mu_0 i}{4\pi d}\] (Perpendicular to the plane in outward direction)
At point Q, the magnetic field due to wire W1 is given by
\[B_1 = \frac{\mu_0 i}{4\pi d}\] (Perpendicular to the plane in inward direction)
At point Q, the magnetic field due to wire W2 is given by
B2 = 0
\[\Rightarrow B_{net} = \frac{\mu_0 i}{4\pi d}\] (Perpendicular to the plane in inward direction)
At point R, the magnetic field due to wire W1 is given by
B1 = 0
At point R, the magnetic field due to wire W2 is given by
\[\Rightarrow B_{net} = \frac{\mu_0 i}{4\pi d}\] (Perpendicular to the plane in inward direction)
\[\Rightarrow B_{net} = \frac{\mu_0 i}{4\pi d}\] (Perpendicular to the plane in inward direction)
At point S, the magnetic field due to wire W1 is given by
\[B_1 = \frac{\mu_0 i}{4\pi d}\] (Perpendicular to the plane in outward direction)
At point S, the magnetic field due to wire W2 is given by
B2 = 0
\[\Rightarrow B_{net} = \frac{\mu_0 i}{4\pi d}\] (Perpendicular to the plane in outward direction)
Hence, the magnitude of the magnetic field at points P, Q, R and S is \[\frac{\mu_0 i}{4\pi d}\] .
APPEARS IN
संबंधित प्रश्न
Two concentric circular coils X and Y of radii 16 cm and 10 cm, respectively, lie in the same vertical plane containing the north to south direction. Coil X has 20 turns and carries a current of 16 A; coil Y has 25 turns and carries a current of 18 A. The sense of the current in X is anticlockwise, and clockwise in Y, for an observer looking at the coils facing west. Give the magnitude and direction of the net magnetic field due to the coils at their centre.
Two identical circular coils, P and Q each of radius R, carrying currents 1 A and √3A respectively, are placed concentrically and perpendicular to each other lying in the XY and YZ planes. Find the magnitude and direction of the net magnetic field at the centre of the coils.
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?
Consider the situation shown in figure. The straight wire is fixed but the loop can move under magnetic force. The loop will
Figure shows a square loop ABCD with edge-length a. The resistance of the wire ABC is r and that of ADC is 2r. Find the magnetic field B at the centre of the loop assuming uniform wires.
Two circular coils of radii 5.0 cm and 10 cm carry equal currents of 2.0 A. The coils have 50 and 100 turns respectively and are placed in such a way that their planes as well as the centres coincide. If the outer coil is rotated through 90° about a diameter, Find the magnitude of the magnetic field B at the common centre of the coils if the currents in the coils are (a) in the same sense (b) in the opposite sense.
A circular loop of radius R carries a current I. Another circular loop of radius r(<<R) carries a current i and is placed at the centre of the larger loop. The planes of the two circles are at right angle to each other. Find the torque acting on the smaller loop.
Find the magnetic field B due to a semicircular wire of radius 10.0 cm carrying a current of 5.0 A at its centre of curvature.
A piece of wire carrying a current of 6.00 A is bent in the form of a circular are of radius 10.0 cm, and it subtends an angle of 120° at the centre. Find the magnetic field B due to this piece of wire at the centre.
A circular loop of radius r carries a current i. How should a long, straight wire carrying a current 4i be placed in the plane of the circle so that the magnetic field at the centre becomes zero?
A circular coil of 200 turns has a radius of 10 cm and carries a current of 2.0 A. (a) Find the magnitude of the magnetic field \[\vec{B}\] at the centre of the coil. (b) At what distance from the centre along the axis of the coil will the field B drop to half its value at the centre?
A circular loop of radius 4.0 cm is placed in a horizontal plane and carries an electric current of 5.0 A in the clockwise direction as seen from above. Find the magnetic field (a) at a point 3.0 cm above the centre of the loop (b) at a point 3.0 cm below the centre of the loop.
The magnetic field at a distance r from a long wire carrying current I is 0.4 tesla. The magnetic field at a distance 2 r is ______.
If we double the radius of a coil keeping the current through it unchanged, then the magnetic field at any point at a large distance from the centre becomes approximately.
A short bar magnet has a magnetic moment of 0. 65 J T-1, then the magnitude and direction of the magnetic field produced by the magnet at a distance 8 cm from the centre of magnet on the axis is ______.
The fractional change in the magnetic field intensity at a distance 'r' from centre on the axis of the current-carrying coil of radius 'a' to the magnetic field intensity at the centre of the same coil is ______.
(Take r < a).
Two horizontal thin long parallel wires, separated by a distance r carry current I each in the opposite directions. The net magnetic field at a point midway between them will be ______.
