Physics HL · Chapter 20: Electromagnetic Induction
20.2 Faraday's Law and Flux Linkage
Move from single-loop flux to multi-turn flux linkage and formal rate-of-change induction laws.
Estimated time: 32 minutes
Flux Linkage N Phi
Real coils usually have many turns, so induction depends on total flux linkage N Phi, not just flux through one loop. If each turn sees the same flux, linkage scales directly with N. This is the first reason transformers and generators use many turns: induced emf can be increased without increasing field strength.
When a loop is partly outside a field region, only the overlapping area contributes. That means induction tasks often become geometry-plus-time problems: write area overlap as a function of time, then convert it to flux and differentiate or use finite differences.
Faraday's Law as a Rate Law
Magnitude comes from the rate of change of linkage; the minus sign encodes opposition to change (formalized by Lenz's law).
In many IB questions you can use the average form epsilon_avg = -Delta(N Phi)/Delta t over a known interval. For sinusoidal or continuously changing systems, instantaneous values matter and differential form is cleaner. Both are the same law, used at different resolution.
A useful exam check: if the field is static, loop area is fixed, and orientation is fixed, then flux is constant and induced emf must be zero. Students often expect current just because a field exists, but induction needs change, not just presence.
Simulation: Flux Linkage and Rate-of-Change Tracker
Vary overlap fraction and flux-change rate to see direct consequences for dPhi/dt, induced emf, and sign conventions.
Flux Phi
-1.50e-3 Wb
dPhi/dt
-7.07e-4 Wb/s
Induced emf
7.07e-4 V
Induced field
out of the page
Current direction
counterclockwise (CCW)
Test Yourself
A coil has its number of turns doubled while dPhi/dt for each turn stays unchanged. What happens to induced emf magnitude?