Lenz's Law
This lesson covers:
- Introducing Lenz's law regarding the direction of induced EMF and current.
- Explaining Lenz's law for induction in a coil.
- Demonstrating Lenz's law for a conducting rod moving in a magnetic field.
Lenz's law and direction of induced EMF
Lenz's law provides insight into the direction of the induced EMF and the resultant current. It states that the induced EMF's direction will be such that it opposes the change in magnetic flux that produced it. This opposition is represented by the minus sign in Faraday's law, indicating the nature of the induced EMF to resist the change causing it.
Lenz's Law - The direction of the induced EMF and the resulting current will be such that it creates a magnetic field opposing the change in the original magnetic flux.
This opposition means that any current induced in coils or conductors will generate magnetic fields that counteract the change in the initial magnetic field, thus resisting it.
Lenz's law applied to a coil
For a coil experiencing changes in magnetic flux:
- An increasing magnetic field induces a current that creates an opposing magnetic field to counteract the strengthening magnetic field.
- A decreasing magnetic field induces a current that creates a magnetic field aiding the original field's direction to counteract the weakening magnetic field.
Therefore, the direction of the induced current will depend on whether the magnetic field strength is increasing or decreasing.
Lenz's law for a moving conducting rod
For a conducting rod moving through a magnetic field, the induced magnetic field within the rod will arrange its poles to oppose the rod's motion through the external field. This induced opposition affects the rod's motion by creating a repulsive force, demonstrating Lenz's law in action by hindering the motion that generates the induction.