To induce an e.m.f. in a coil, the linking magnetic flux

The formula for induced e.m.f. in a coil due to change in magnetic flux through the coil is (here A = area of the coil, B = magnetic field)

Assertion (A): Lenz's law does not violets the principle of conservation of energy. Reason (R): Induce e.m.f. never opposes the change in magnetic flux that causes the e.m.f.

The induced e.m.f. in a coil does not depend on

Lenz's law violates the principle of conservation of energy. Reason: Induced e.m.f. opposes always the change in magnetic flux responsible for its production.

The phase difference between the flux linkage and the induced e.m.f. in a rotating coil in a uniform magnetic field

Coil 1 has L_(1) = 25 mH and N_(1) = 100 turns. Coil 2, has L_(2) = 40 mH and N_(2) = 200 turns. The coils are fixed in place, their mutual inductance M is 9.0 mH. A 6.0 mA current in coil 1 is changing at the rate of 4.0 A/s. (a) What magnetic flux phi_(12) 12 links coil 1, and (b) what self-induced emf appears in that coil? (c) What magnetic flux phi_(21) links coil 2, and (d) what mutually induced emf appears in that coil?

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

For a coil rotating in a uniform magnetic field, in which position of the coil is the emf induced in the maximum? What is the magnetic flux through the coil in this position?

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