2) Take A 40-pF capacitor and charge it to a potential difference of 500 V. Then...

A 13 pF capacitor is connected in series with a 5 pF and 9 pF capacitor...

A 13 pF capacitor is connected in series with a 5 pF and 9 pF capacitor that are connected in parallel. The three capacitors are connected to a 26 V battery. A) What is the equivalent capacitance of the circuit? B) How much charge is on the 13 pF capacitor? C) What is the potential difference across the 5 pF capacitor? D) A parallel plate capacitor of plate area A and plate separation d is fully charged using a battery...

A 13 pF capacitor is connected in series with a 5 pF and 9 pF capacitor...

A 13 pF capacitor is connected in series with a 5 pF and 9 pF capacitor that are connected in parallel. The three capacitors are connected to a 26 V battery. (Show all your work!) A) What is the equivalent capacitance of the circuit? B) How much charge is on the 13 pF capacitor? C) What is the potential difference across the 5 pF capacitor? D) A parallel plate capacitor of plate area A and plate separation d is fully...

A) Charge a 3 microfarad capacitor by hooking it to a battery (a voltage difference supplier)...

A) Charge a 3 microfarad capacitor by hooking it to a battery (a voltage difference supplier) that has a potential difference of 15 volts. a) What is the charge on one the capacitor plates? b) If the plate separation is 2 x 10-6 meters, what is the electric field between the plates? c) How much energy is stored? B) Leaving the battery connected, you insert a dielectric with a constant of 3.7 between the plate of the capacitor. a) What...

A 2.70 μF capacitor is charged to 500 V and a 3.95 μF capacitor is charged...

A 2.70 μF capacitor is charged to 500 V and a 3.95 μF capacitor is charged to 525 V . a) These capacitors are then disconnected from their batteries, and the positive plates are now connected to each other and the negative plates are connected to each other. What will be the potential difference across each capacitor? b) What will be the charge on each capacitor? c) What is the voltage for each capacitor if plates of opposite sign are...

A 28.2×10-6 F capacitor C1 is charged to a potential difference of 87.63 V. The capacitor...

A 28.2×10-6 F capacitor C1 is charged to a potential difference of 87.63 V. The capacitor is then removed from the charging source and then connected across a second initially uncharged capacitor C2. The final potential difference across each capacitor after they have been connected in 5.57 V. Find the value of the capacitance C2 ?

A potential of 24.0 V is applied across a 3.25 pF parallel plate capacitor. The plate...

A potential of 24.0 V is applied across a 3.25 pF parallel plate capacitor. The plate separation is 2.00 mm. a). If the plates are identical, what is the surface area of each plate? b). How much charge is on the plates? c). What is the electric field between the plates? d). If an electron is released at the negative plate with what velocity will it strike the positive plate? e). What force did the electron experience while it was...

An 8 pF capacitor is connected in series to a parallel combination of a 15 pF...

An 8 pF capacitor is connected in series to a parallel combination of a 15 pF and a 3 pF capacitor, the circuit is then charged using a battery with an emf of 34 V. a) What is the potential difference across the 8 pF capacitor? b) What is the charge on the 3 pF capacitor? c) How much energy is stored in the 15 pF capacitor?

A potential difference of 330 V is applied to a series connection of two capacitors, of...

A potential difference of 330 V is applied to a series connection of two capacitors, of capacitance C1 = 1.60 μF and capacitance C2 = 8.20 μF. (a) What is the charge q1 on capacitor 1? C (b) What is the potential difference V1 across capacitor 1? V (c) What is the charge q2 on capacitor 2? C (d) What is the potential difference V2 on capacitor 2? V The charged capacitors are then disconnected from each other and from...

A 2.50-μF capacitor is charged to 754 V and a 6.80-μF capacitor is charged to 574...

A 2.50-μF capacitor is charged to 754 V and a 6.80-μF capacitor is charged to 574 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.] Determine the potential difference across the first capacitor. Determine the potential difference across the second capacitor. Determine the charge...

A 140-pF capacitor and a 560-pF capacitor are both charged to 2.10 kV. They are then...

A 140-pF capacitor and a 560-pF capacitor are both charged to 2.10 kV. They are then disconnected from the voltage source and are connected together, positive plate to negative plate and negative plate to positive plate. (a) Find the resulting potential difference across each capacitor. V140 pF = _____kV V560 pF = _____kV (b) Find the energy lost when the connections are made. _____µJ