Final answer:
Using Faraday's law of induction, the coefficient of self-inductance (L) is calculated as 0.08 H. However, this result is not within the provided options; the closest is 0.1 H, which may indicate a typo in the options.
Step-by-step explanation:
To find the coefficient of self-inductance of the coil, we can use the formula for induced electromotive force (emf) given by Faraday's law of induction, which is:
E = -L ΔI/Δt
Where:
- E is the induced emf
- L is the coefficient of self-inductance
- ΔI is the change in current
- Δt is the change in time
According to the question:
- E = 2 V
- ΔI = 10 A - 0 A = 10 A
- Δt = 0.40 s
Plugging these values into the formula, we get:
2 V = -L (10 A) / 0.40 s
Solving for L, the self-inductance of the coil:
L = -2 V × 0.40 s / 10 A = 0.08 H
However, since the induced emf (E) is in the direction to oppose the change in current, we take the magnitude of L which gives us:
L = 0.08 H
This is not one of the options provided, but this result indicates that the closest option would be (b) 0.1 H, which may suggest that there is a possible typo in the provided options.