The magnetometer of the previous problem is used with the same magent in `Tan-B` position. Where should the magnet be placed to produce a `37^@` deflection of the needle?

The needle of a deflection magnetometer deflects through 45^@ from north to south when the instrument is used in Tan-A position with a magnet of length 10cm placed at a distance of 25cm. (a) Find the magnetic moment of the magnet if the earth's horizontal magnetic field is 20 muT . (b) If the magnetometer is used in Tan-B position with the same magnet at the same separation from the needle, what will be the deflection?

A deflection megnetometer is placed with its arms in north-south direction. How and where should a short magnet having M/B_H = 40 A m^2 T(-1) be placed so that the needle can stay in any position?

A short magnet produces a deflection of 37^@ in a deflection magnetometer in Tan-A position when placed at a separation of 10cm from the needle. Find the ration of the magnetic moment of the magnet to the earth's horizontal magentic field.

A short bar magnet placed with its axis at 30^@ with an external field of 800 G experiences a torque of 0.016 Nm . a. What is the magnetic moment of the magnet ? b. What is the work done in moving it from its most stable to most unstable position ? c. The bar magnet is replaced by a solenoid of cross - sectional area 2xx10^(-4) m^2 and 1000 turns, but of the same magnetic moment . Determine the current flowing through the solenoid.

Consider the situation described in the previous problem. Where should a point source be placed on the principal axis so that the two images form at the same place ?

A short magnet makes 40 oscillations per minute when used in an oscillation magnetometer at a place where the earth's horizontal magnetic field is 25 muT . Another short magnet of magnetic moment 1.6 A m^2 is placed 20 cm east of the oscillating magnet. Find the new frequency of oscillation if the magnet has its north pole (a) towards north and (b) towards south.

A particle A having a charge of 2.0xx 10^(-6) C and a mass of 100 g is placed at the bottom of a smooth inclined plane of inclination 30@ . Where should another particle B, having same charge and mass, be placed on the incline so that it may remain in equilibrium?

Shows a situation similar to the previous problem. All parameters are the same except that a battery of emf epsilon and a variable resistance R are connected wires. Let theta be the angle made by the rod from the horizontal position (shown in the figurer), measuredin the clockwise direction. During the part of the motion Oltthetaltpi/4 the only forces acting on the rod are gravity and the forces exerted by the magnetic field and the pivot. However, during the part of the motion, the resistance R is varied in such a way that the rod continues to rotate with a constant angular velocity omega . Find the value of R in terms of the given quantities.