Why does self-inductance still allow variation of current in circuit?

Question

Taking a solenoid as an example, when constant current $i$ is passed through the solenoid constant flux is seen. But when the current starts to vary, the magnetic field created by a changing current in the solenoid itself induces a voltage in the same circuit. And Self-induced voltage creates a self-induced current in the solenoid that has opposite direction with respect to the original current, and this should be opposing the changing current, so when it does, the changing current and self-induced current have to get balanced and cancel each other. And there should never be a change in current because as soon as we try to change the current, self-induced current is produced in the solenoid and it opposes the change. But this doesn't seem to happen, the current still changes. Why?

Answer 1

The problem with your reasoning is that you assume the induced EMF always completely cancels the changing magnetic flux due to a time varying current, preventing any change in the current in the first place, which is not correct. If there were no change in the current, there wouldn't be an induced EMF.

To analyze how the current will be changing, it's not very useful to think of it as being made up of two components: the applied current, and the current induced by the changing magnetic flux. Instead, we consider the total current (which is what is measurable) that includes both of these components.

Suppose that changes in the magnetic flux through the inductor is only caused by the applied current, i.e. there is no external time-varying magnetic flux through the inductor. A current $i$ through the inductor induces a magnetic flux of $\Phi = Li$, where $L$ is the inductance. According to Faraday's Law, the induced EMF is $$\mathcal{E}=-\frac{d \Phi}{dt}=-L\frac{d i}{dt}.$$ This EMF opposes sudden changes in the current through the inductor. In practice, we usually say that the "voltage" across the inductor is $v=L\frac{di}{dt}$, and demand that Kirchhoff's Voltage Law hold (sum of voltage drops along a loop is zero). This gives the correct voltage drops across the rest of the circuit.

What does this mean? How does the current change? It depends on the circuit the inductor is connected to. If you connect an ideal inductor to an ideal voltage supply, and suddenly increase the supply voltage from $0$ to $V_0$, you must solve $$V_0=L \frac{di}{dt}$$ with initial condition $i(0)=0$. The solution is $$i(t)=\frac{V_0}{L}t,$$ i.e. the current will linearly increase in time.

If on the other hand you have a current source with a parallel output resistance $R$ connected to an inductor, and turn on the current to $I_0$ at $t=0$, the solution is $$ i(t) = I_0 \left[1 - \exp\left(\frac{-t}{L/R}\right) \right], $$ i.e. the current will gradually increase to the supply current.

Answer 2

Well as much of your question that I could perceive is the induced current should cancel given current and net current should be zero If this is what you asked then yes it is true but just for an ideal case in which, when applied current is changed the flux through coil changes and induces an equal but opposite emf to the applied emf and hence cancels the current but in practical inductors the induced emf never equals the applied emf and net current flows through the inductor!