In an inductor of self-inductance L=2 mH, current changes with time according to relation `i=t^(2)e^(-t)`. At what time emf is zero ?

In an inductor of inductance L=100mH , a current of I=10A is flowing. The energy stored in the inductor is

The inductors of self inductance L_(1) and L_(2) are put in series .

The position vector of a particle changes with time according to the relation vec(r ) (t) = 15 t^(2) hat(i) + (4 - 20 t^(2)) hat(j) What is the magnitude of the acceleration at t = 1?

In a certain circuit current changes with time according to i=2sqrt(t) RMS value of current between t=2s to t=4s will be

The current in a coil of self-inductance 2.0 H is increasing according to I=2 sin t^(2) ampere. Find the amount of energy spent during the period when the current charges from zero to 2A.

In Fig, the mutual inductance of a coil and a very long straight wire is M , coil has resistance R and self-inductance L . The current in the wire varies according to the law I = at , where a is a constant and t is the time, the time dependence of current in the coil is

For a coil having L=4 mH , current flow through it is I=t^3.e^(-t) then the time at which emf becomes zero

Two identical inductance carry currents that vary with time according to linear laws (as shown in figure). In which of two inductance is the self induction emf greater?