A long solenoid of cross-sectional area `5.0 cm^2` is wound with 25 turns of wire per centimetre. It is placed in the middle of a closely wrapped coil of 10 turns and radius 25 cm as shown.


(a) What is the emf induced in the coil when the current through the solenoid is decreasing at a rate `-0.20 A//s` ?
(b) What is the electric field induced in the coil?

A long solcnoid of length 1m, cross-sectional area 10cm^(2) , having 1000 turns has wound about its centre a small coil of 20 turns. Compute the mutual inductance of the pair of solenoid and the coil . What is the induced EMF in the coil when the current in the solenoid changes at the rate of 10 A//s ?

A 0.5 m long solenoid of 10 turns/cm has area of cross-section 1 cm^(2) . Calculate the voltage induced across its ends if the current in the solenoid is changed from 1 A to 2 A in 0.1 s.

a. Calculate the inductance of an air core solenoid containing 300 turns if the length of the solenoid is 25.0cm and its cross -sectional area is 4.00cm^2 . b. Calculate the self -induced emf in the solenoid if the current through it is decreasingg at the rate of 50.0A//s .

A current l = 1.5 A is flowing through a long solenoid of diameter 3.2 cm, having 220 turns per cm. At its centre, a 130 turn closely packed coil of diameter 2.1 cm is placed such that the coil is coaxial with the long solenoid. The current in the solenoid is reduced to zero at a steady rate in 25 ms. What is the magnitude of emf induced in the coil while the current in the solenoid is changing?

Through a long solenoid of diameter 4.1 cm, having 100 turns per cm, a current I = 1A is flowing. At its centre, a 60 turns closely packed coil of diameter 3.1 cm si placed such that the coil is coaxial with the long solenoid. The current in the solenoid is reduced to zero at a steady rate in 10 ms. What is the magnitude of emf induced in the coil while the current in the solenoid is changing?

A long straight solenoid of cross-sectional diameter d = 5 cm and with n = 20 turns per one cm of its length has a round turn of copper wire of cross-sectional area S = 1.0 mm^(2) tightly put on its winding. Find the current flowing in the turn if the current in the solenoid winding is increased with a constant velocity dotI = 100 A//s . The inductance of the turn is to be neglected.

A long solenoid of diameter 0.1 m has 2 xx 10^4 turns per metre. At the centre of solenoid, a coil of 100 turns and radius 0.01 m is placed with its axis coinciding with the solenoid axis. The current in the solenoid reduces at a constant rate to 0 A from 4 A in 0.05 s. If the resistance of the coil is 10 pi^2 Omega , the total charge flowing through the coil during this time is: