The magnetic flux linked with a coil is `phi` and the emf induced in it is `e`.

Whenever the magnet flux linked with a coil changes, then is an induced emf in the circuit. This emf lasts

The magnetic flux linked with a coil (in Wb) is given by the equation phi = 5t^2 + 3t +16 . The magnetic of induced emf in the coil at fourth second will be

The magnetic flux linked with a coil, in webers is given by the equation phi=3t^(2)+4t+9 . Then, the magnitude of induced emf at t = 2 s

The magnetic flux linked with a coil is given by an equation phi (in webers ) = 8t^(2)+3t+5 . The induced e.m.f. in the coil at the fourth second will be

A coil of self-inductance L is placed in an external magnetic field (no current flows in the coil). The total magnetic flux linked with the coil is phi . The magnetic field energy stored in the coil is

When ever the flux linked with a coil changes, then

STATEMENT - 1 : Whenever there is a change in flux linked with a coil in a circuit, an induced current is set up in it. and STATEMENT - 2 : Whenever there is a change in flux linked with a coil in a circuit, an induced emf is set up in it.

The magnetic flux linked with a coil, in weber, is given by the equation: ϕ=5t^2+3t+16. The induced e.m.f. in the coil in the fourth second will be

(A): When a conducting wire loop which is inside a uniform magnetic field directed perpendicular to its planes is moving with uniform velocity, an e.m.f is induced in it. (R) : When magnetic flux linked with a conducting wire loop changes with time an e.m.f is induced in the coil.

A magnet is moving towards a coil along its axis and the emf induced in the coil is ε . If the coil also strats moving towards the magnet with the same speed, the induced emf will be A. ε/2 B. ε C. 2ε D. 4ε