Lenz's Law/Conservation of Energy

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In summary, Lenz's Law states that an induced voltage will always act to oppose the change that caused it, ensuring that no free energy is created and thus remaining consistent with the principle of conservation of energy. This can be seen through the example of a bar magnet being put through a coil, where the induced current's magnetic field opposes the motion of the magnet, preventing any free energy from being created.
  • #1
KatieKangaroo
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Show that Lenz's Law is consistent with the principle of conservation of energy.
Lenz's Law states that an induced voltage will always act to appose the change that caused it. I'm just struggling to link this with the principle of conservation of energy. Can anyone help me out?
 
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  • #2
Lenz's law says a little more than that; stretch it out and it becomes:

An increasing voltage flows through a coil. This coil creates an increasing magnetic field (increasing flux). This change in flux will induce a voltage in a second coil. The induced voltage ( if it can) will cause an induced current. THis induced current will create an increasing magnetic field, and therefore a secondary changing flux. THis secondary change in flux will oppose the original change in flux that caused the induced voltage. The induced change in flux from the second coil will then induce another voltage in the first coil. This voltage will then oppose the original voltage.

This way you can't get one current to create a second current without losing the first one.
 
  • #3
KatieK: (in response to your PM)

If you are talking about a bar magnet being put through a coil, Lenz's Law is simpler (not simple, just simpler than two coils).

If a current is induced in the coil when a magnet is put through it, then the energy of this current could do work. If the force of pushing the magnet were somehow not resisted, then you could keep the mechanical energy (the KE of the moving bar magnet) while gaining electrical energy (of a current moving due to a voltage).

The induced magnetic field is what opposes the moving magnet and "takes away" the KE. IF the induced current caused a magnetic field that attracst the magnet, then you would get the electrical energy, plus an increase in KE (since the attraction would pull the bar magnet into the coil). Hence, the fact that the induced current creates a magnetic field that opposes the motion of the magnet means that no free energy is created.
 

1. What is Lenz's Law?

Lenz's Law is a fundamental principle of physics that states that the direction of an induced electromagnetic force (emf) always opposes the change in magnetic flux that produced it. This means that when a magnetic field changes, it creates an opposing force that opposes the change.

2. How does Lenz's Law relate to the conservation of energy?

Lenz's Law is closely related to the law of conservation of energy, which states that energy cannot be created or destroyed, only transformed from one form to another. Lenz's Law ensures that energy is conserved in electromagnetic systems by preventing a magnetic field from changing without an equal and opposite force being produced.

3. What is the practical importance of Lenz's Law?

Lenz's Law has many practical applications in engineering, particularly in the design and operation of electric motors and generators. It also explains phenomena such as electromagnetic induction and eddy currents, and is essential for understanding the behavior of magnetic fields in various systems.

4. Is Lenz's Law always true?

Yes, Lenz's Law is a fundamental law of physics and is always true. It has been extensively tested and has never been found to be violated. It is a crucial principle for understanding and predicting the behavior of electromagnetic systems.

5. Can Lenz's Law be mathematically expressed?

Yes, Lenz's Law can be mathematically expressed as an equation:
emf = -N(dΦ/dt), where emf is the induced electromotive force, N is the number of turns in a coil, and dΦ/dt is the rate of change of magnetic flux. This equation shows the relationship between the induced emf and the change in magnetic flux that produces it, with the negative sign indicating the opposing nature of the force.

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