PHYSICS II: 6) A 12.00 nF and a 6.00 nF capacitor are connected in series with...
Example 23.1: A 60.0 pF and a 30.0 pF capacitor are connected in series with a 12 Volt battery. Find: a) the total capacitance; b) the charge on each capacitor (same for both). Example 23.2: A 3.42 nF capacitor is connected to a 36.0 ohm resistor, a 6 volt battery and an open switch. A) Find the time constant for the RC circuit. B) What is the initial current through the battery when the switch is closed? C) After a...
16. A 3.0 uF and a 5.0 uF capacitor are connected in series with a 12 V battery. Find the equivalent capacitance. Find the charge on each capacitor. Find the potential drop (or voltage) across each capacitor.
1. A 450 nF capacitor is initially uncharged. The capacitor is connected in series with a 2,500 resistor and a 6.00 V ideal battery. The circuit is “closed” allowing current to flow and the capacitor to start charging. a. What is the time constant of this RC circuit? b. What is the current through the resistor when the circuit is first “closed”? c. How much time is required for the voltage across the capacitor to reach 5.00 V? d....
Example 23.1: A 60.0 pF and a 30.0 pF capacitor are connected in series with a 12 Volt battery. Find: a) the total capacitance; b) the charge on each capacitor (same for both).
Example 23.2: A 3.42 nF capacitor is connected to a 36.0 ohm resistor, a 6 volt battery and an open switch. A) Find the time constant for the RC circuit. B) What is the initial current through the battery when the switch is closed? C) After a long time, what is the potential difference across the capacitor, and across the resistor?
2. What if the two capacitor of problem 2, are now connected in series and tow a 9.0V battery. Find (a) the equivalent capacitance of the combination, (b) the potential difference across each capacitor, and (c) the charge on each capacitor.
A physics instructor performs a demonstration where a current-carrying wire is made to levitate. The wire has a mass per unit length of 0.590 g/cm and carries a current of 2.06 A horizontally to the south. Find the magnitude and direction of the minimum magnetic field needed to lift this wire vertically upward. (Enter the magnitude in T.) Magnitude:? Direction:?
You are given a circuit with a switch, resistor, capacitor and battery all in series. The capacitor is initially discharged and begins charging at t=0.0000s, when the switch is closed. The capacitance is C=0.0100F, the resistance is R=80.0000Ohms, and the battery EMF-15.0000 Volts. At what time is the voltage across the capacitor half the maximum? (in seconds) Your Answer: Answer A uniform magnetic field points toward the right. The direction for a positive moving charge is 1.0000, where "1" means...
1. The potential in a region between x-Oand x-600 mis V-e+bs, where α-198V and b -5.50 V/m a. Determine the potential atxo. 19.8V Determine the potential at x-3.00 m. 3.3V Determine the potential at x 6.00 m-13.2V Determine themagnitude and direction of the electric field Determine the magnitude and direction of the electric field at x-3.00 m5 Determine the magnitude and direction of the electric field at x-6.00 m. 5.5 Vim b. -0.53 2. Consider the following figure C2 (a)...
A capacitor of capacitance C= 2.5 μF is initially uncharged. It is connected in series with a switch of negligible resistance, a resistor of resistance R= 14.5 kΩ, and a battery which provides a potential difference of VB = 160 V.Part (a) Immediately after the switch is closed, what is the voltage drop Vc, in volt across the capacitor?Part (b) Immediately after the switch is closed, what is the voltage drop VR, in volt: across the resistor?Part (c) Immediately after...