A 23.1 ?F capacitor is charged by a 146.3 V power supply, then disconnected from the...

A 17.0-μF capacitor is charged by a 150.0-V power supply, then disconnected from the power and...

A 17.0-μF capacitor is charged by a 150.0-V power supply, then disconnected from the power and connected in series with a 0.280-mH inductor. a) Calculate the energy stored in the inductor at t = 1.30 ms. (Express your answer to three significant figures and include the appropriate units.)

A 13.0-μFμF capacitor is charged by a 125.0-VV power supply, then disconnected from the power and...

A 13.0-μFμF capacitor is charged by a 125.0-VV power supply, then disconnected from the power and connected in series with a 0.270-mHmH inductor. f =2.69 kHz WHEN T = 0 U = 0.102 J Calculate the energy stored in the inductor at t = 1.30 ms.

An initially uncharged 12 μF capacitor charged by a 12 V power supply (battery) connected in...

An initially uncharged 12 μF capacitor charged by a 12 V power supply (battery) connected in series with a 100 Ω resistor. i. What is the total energy stored in the capacitor when it reached the fully charged situation? ii. What is the total energy supplied by the power supply during this time? iii. Does the capacitor store the total energy supplied by the battery? Otherwise, explain how the energy supplied by the battery used in the circuit.

A 1.10-µF capacitor is charged by a 30.0-V power supply. The fully charged capacitor is then...

A 1.10-µF capacitor is charged by a 30.0-V power supply. The fully charged capacitor is then discharged through a 9.7-mH inductor. Find the maximum current in the resulting oscillations.

A 10 muF capacitor is charged to 120V and then disconnected from the power supply. If...

A 10 muF capacitor is charged to 120V and then disconnected from the power supply. If a second uncharged capacitor with capacitance of 50muF is connected across the first capacitor, what would be the resulting voltage across their parallel combination?

A 4.85 μF capacitor is initially charged to a potential of 16.4 V . It is...

A 4.85 μF capacitor is initially charged to a potential of 16.4 V . It is then connected in series with a 3.50 mH inductor. 1.What is the total energy stored in this circuit? Express your answer in joules to three significant figures. 2.What is the maximum current in the inductor? Express your answer in amperes to three significant figures. 3.What is the maximum current in the inductor? Express your answer in amperes to three significant figures.

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.)

A 2.50 F capacitor is charged to 857 V and a 6.80F capacitor is charged to...

A 2.50 F capacitor is charged to 857 V and a 6.80F capacitor is charged to 652 V. These capacitors are then disconnected from their batteries. Next the positive plates are connected to each other and the negative plates are connected to each other. What will be the potential difference across each and the charge on each? [Hint: charge is conserved.]

A 33 nf capacitor is connected to a 9.00 V battery and fully charged. The capacitor...

A 33 nf capacitor is connected to a 9.00 V battery and fully charged. The capacitor is then disconnected from the battery, an an insulator having a dielectric constant is inserted between the plates of the charged capacitor. What is the energy stored in the capacitor with the dielectric inserted?

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