A bar magnet of length l and magnetic dipole moment M is bent to form an arc which subtends an angle of at centre. The new magnetic dipole moment will be
1.
2.
3.
4.
A small bar magnet is placed with its north pole facing the magnetic north pole. The neutral points are located at a distance r from its centre. If the magnet is rotated by 180o, the neutral point shall be obtained at a distance of:
1. \(2r\)
2. \(\sqrt{2}r\)
3. \(2^{\frac{1}{3}}r\)
4. \(\frac{r}{2\sqrt{2}}\)
Magnetic field lines
1. Cannot intersect
2. Are always closed curves
3. Can pass through vacuum
4. All of these
Two small bar magnets are placed in the air at a distance r apart. The magnetic force between them is proportional to:
(1)
(2)
(3)
(4)
A short magnetic dipole is placed at the origin with its dipole movement directed along the +x-axis. If magnetic field induction at a point P (r, 0) is \(B\hat{i}\), the magnetic field induction at point Q (0, 2r) will be:
1. \(-\frac{B}{16}\hat{i}\)
2. \(-\frac{B}{8}\hat{j}\)
3. \(\frac{B}{16}\hat{j}\)
4. \(-\frac{B}{16}\hat{j}\)
Oersted is a unit of :
(1) Dip
(2) Magnetic intensity
(3) Magnetic moment
(4) Pole strength
The magnetic field at a point x on the axis of a small bar magnet is equal to the field at a point y on the equator of the same magnet. The ratio of the distances of x and y from the centre of the magnet is:
1.
2.
3.
4.
A magnet of magnetic moment 20 C.G.S. units are freely suspended in a uniform magnetic field of intensity 0.3 C.G.S. units. The amount of work done in deflecting it by an angle of in C.G.S. units is
(1) 6
(2)
(3)
(4) 3
The magnetic field due to a short magnet at a point on its axis at a distance X cm from the middle point of the magnet is 200 Gauss. The magnetic field at a point on the neutral axis at a distance of X cm from the middle of the magnet is:
1. 100 Gauss
2. 400 Gauss
3. 50 Gauss
4. 200 Gauss