1. Self-Inductance and Circuits LC circuits

2. 0 1τ 2τ 3τ 4τ 63% ε /R I t Recall: RC circuit, increasing current

3. I t 0τ τ 2τ 3τ 4τ 0.37 I 0 IoIo Recall: RC circuit, decreasing current

4. Question: What happens if we put a capacitor in the circuit, along with R, or L, or both?

5. LC circuits The switch is closed at t =0; Find I (t). C L I + - A capacitor is connected to an inductor in an LC circuit Assume the capacitor is initially charged and then the switch is closed Assume no resistance and no energy losses to radiation

6. Oscillations in an LC Circuit, 1 The capacitor is fully charged –The energy U in the circuit is stored in the electric field of the capacitor –The energy is equal to Q 2 max /2C –The current in the circuit is zero –No energy is stored in the inductor The switch is closed

7. Oscillations in an LC Circuit, 2 The current is equal to the rate at which the charge changes on the capacitor (dQ/dt) –As the capacitor discharges, the energy stored in the electric field decreases –Since there is now a current, some energy is stored in the magnetic field of the inductor –Energy is transferred from the electric field to the magnetic field

8. Oscillations in an LC Circuit, 3 The capacitor becomes fully discharged –It stores no energy –All of the energy is now stored in the magnetic field of the inductor –This energy is equal to ½ LI 2 –The current reaches its maximum value The current now decreases in magnitude, recharging the capacitor with its plates having opposite their initial polarity

9. Oscillations in an LC Circuit, 4 Eventually the capacitor becomes fully charged and the cycle repeats The energy continues to oscillate between the inductor and the capacitor The total energy stored in the LC circuit remains constant in time and equals:

10. LC Circuit Analogy to Spring-Mass System The kinetic energy (½ mv 2 ) of the spring is analogous to the magnetic energy (½ L I 2 ) stored in the inductor The potential energy ½kx 2 stored in the spring is analogous to the electric potential energy ½CV max 2 stored in the capacitor At any point in the cycle, energy is shared between the electric and magnetic fields

11. LC circuits The switch is closed at t =0; Find I (t). C L I Which can be written as (remember, P=VI): + - Looking at the energy loss in each component of the circuit gives us: E L +E C =0

12. Solution

13. Charge and Current in an LC Circuit The charge on the capacitor oscillates between Q max and –Q max The current in the inductor oscillates between I max and –I max Q and I are 90 o out of phase with each other –So when Q is a maximum, I is zero, etc.

14. Energy in an LC Circuit – Graphs The energy continually oscillates between the energy stored in the electric and magnetic fields When the total energy is stored in one field, the energy stored in the other field is zero

15. Example 1: A 1.00-μF capacitor is charged by a 40.0-V power supply. The fully charged capacitor is then discharged through a 10.0-mH inductor. Find the maximum current in the resulting oscillations.

16. Example 2: An LC circuit consists of a 3.30-H inductor and an 840-pF capacitor, initially carrying a 105-μC charge. The switch is open for t < 0 and then closed at t = 0. Compute the following quantities at t = 2.00 ms: a) the energy stored in the capacitor b) the energy stored in the inductor c) the total energy in the circuit.

17. Solution

18. Example 3: The switch in the figure below is connected to point a for a long time. After the switch is thrown to point b, what are a) the frequency of oscillation of the LC circuit, b) the maximum charge that appears on the capacitor, c) the maximum current in the inductor d) the total energy the circuit possesses at t = 3.00 s?

19. Solution

20. Notes About Real LC Circuits In actual circuits, there is always some resistance Therefore, there is some energy transformed to internal energy The total energy in the circuit continuously decreases as a result of these processes