One-eighth of a cycle after the capacitor in an LCcircuit is fully charged Part A: One-eighth...

At time t = 0, the capacitor in an LC circuit is fully charged, and there’s...

At time t = 0, the capacitor in an LC circuit is fully charged, and there’s no current in the circuit. A) Find an expression in terms of L and C, for the time at which the capacitor voltage has half its initial value. Express your answer in terms of the variables L and C. B)Find an expression in terms of L and C, for the time at which the energy stored in the capacitor has half its initial value.Express...

A capacitor is fully charged and then connected in series to an inductor with zero resistance...

A capacitor is fully charged and then connected in series to an inductor with zero resistance wires. This is an ideal L-C circuit that will oscillate the current direction. Explain HOW and WHY this circuit oscillates and discuss energy conservation in this oscillation behavior. Your response should be at least 3 paragraphs to show your mastery of the concepts.

A capacitor is fully charged and then connected in series to an inductor with zero resistance...

A capacitor is fully charged and then connected in series to an inductor with zero resistance wires. This is an ideal L-C circuit that will oscillate the current direction. Explain HOW and WHY this circuit oscillates and discuss energy conservation in this oscillation behavior. Your response should be at least 3 paragraphs to show your mastery of the concepts.

A capacitor is fully charged and then connected in series to an inductor with zero resistance...

A capacitor is fully charged and then connected in series to an inductor with zero resistance wires. This is an ideal L-C circuit that will oscillate the current direction. Explain HOW and WHY this circuit oscillates and discuss energy conservation in this oscillation behavior. Your response should be at least 3 paragraphs to show your mastery of the concepts.

A 3,000 pF capacitor is charged to 200 V and then quickly connected to a 50...

A 3,000 pF capacitor is charged to 200 V and then quickly connected to a 50 mH inductor. (a) Determine the maximum energy (in J) stored in the magnetic field of the inductor. J (b) Determine the peak value of the current (in A). A (c) Determine the frequency of oscillation of the circuit (in Hz). Hz

An ideal capacitor is fully charged and then connected with perfect conducting wires in parallel with...

An ideal capacitor is fully charged and then connected with perfect conducting wires in parallel with a 1500 mH ideal inductor. The frequency of the oscillations of this ideal circuit is 258 kHz. The value of the capacitor is a. 254 pF b. 374 pF c. 122 pF d. 404 pF

An 8.5 nF capacitor is charged up by a 20 V battery. The battery is removed...

An 8.5 nF capacitor is charged up by a 20 V battery. The battery is removed and replaced with a coil of wire. It then takes 7.3 x 10^-5 s for this now LC circuit to undergo a full charging cycle. (a) Calculate the inductance of the coil (b) Calculate the total energy of the circuit (c) Calculate the charge on the capacitor after 1 x 10^-5 s.

In the circuit, the capacitor is fully charged when switch ?S is closed. Calculate the time...

In the circuit, the capacitor is fully charged when switch ?S is closed. Calculate the time needed for the potential energy stored by the circuit to be equally distributed between the capacitor and inductor. The capacitance is ?=60.0 mF and inductance is ?=15.0 H.

A capacitor is charged with a battery. When the energy stored in the capacitor is 1...

A capacitor is charged with a battery. When the energy stored in the capacitor is 1 ??, the capacitor is disconnected from the battery in the circuit and connected in series with an inductor with an inductance of 6 ?H. What is the current in the inductor when the load on the capacitor is half the initial maximum value? (The resistance in the circuit can be neglected.)

(1a) In an oscillating LC circuit in which C = 1.50 nF and L = 3.8...

(1a) In an oscillating LC circuit in which C = 1.50 nF and L = 3.8 mH, the maximum voltage is 4.5 V. Find the maximum charge on the capacitor and the electrical energy stored by the capacitor in this case. (1b) Find the maximum current in the circuit and the magnetic energy stored by the inductor in this case. (1c) What is the period of the oscillations? (1d) If the capacitor is initially fully charged, how long will it...