How Does Energy in an Inductor Change When Disconnected?

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The discussion centers on the behavior of energy in an inductor when it is disconnected from a circuit. The energy stored in the inductor is given by the formula U = 1/2 LI^2. When the switch in the circuit is changed from position A to position B, the energy in the inductor initially decreases but then increases again due to the oscillatory nature of the resonant L-C circuit. This behavior is likened to a child's swing, which oscillates as energy is exchanged between potential and kinetic forms. The conversation highlights the importance of understanding the dynamics of energy transfer in inductors and capacitors within resonant circuits.
AlphaMaleMatt
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Homework Statement



Not really relevant here.

Homework Equations



U = LI^2 -- maybe?

The Attempt at a Solution



http://i.imgur.com/Pq4dOex.png

The picture is there, as well as the answer. Why is that the answer? How do inductors work when completely disconnected, and not in a circuit? Thanks.
 
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The inductor is in a circuit.

1/2 LI^2 (note the prefactor) is indeed the energy stored in an inductor.
 
I'm an idiot. The question asks what happens when the switch is switched over to position B, after being in position A for "a very long time"
 
AlphaMaleMatt said:
I'm an idiot. The question asks what happens when the switch is switched over to position B, after being in position A for "a very long time"

That sine curve in the illustration tells you what happens to UL.

Hint: the instantaneous sum of stored energies in C and L is a constant.
 
rude man said:
That sine curve in the illustration tells you what happens to UL.

Hint: the instantaneous sum of stored energies in C and L is a constant.

I guess I'm just confused as to why the energy in the inductor decreases, but then increases again?
 
I can't give you a good verbal explanation. A publication like the ARRL Handbook can.

Mathematically, the integro-differential equation 1/C∫0t i(t') dt' = -L di/dt is solved with initial condition i(0+) = E/R

where i is the current flowing out of the inductor and into the capacitor. Each term is the voltage at the capacitor and inductor.
 
AlphaMaleMatt said:
I guess I'm just confused as to why the energy in the inductor decreases, but then increases again?
Because the L-C elements represent a resonant circuit (having no resistive losses). Just as a child's swing oscillates when you release it from some height, so does the energy in the analogous L-C circuit.
 

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