Some charge is placed on a capacitor with C1 = 34 μF so that ∆V =...

Two capacitors, one a 4.0 μF capacitor, C1, and the other a 7.0 μF capacitor, C2,...

Two capacitors, one a 4.0 μF capacitor, C1, and the other a 7.0 μF capacitor, C2, are connected in series. If a 90.0 V voltage source is applied to the capacitors, as shown in the figure, find the voltage drop across the 4.0 μF capacitor.​ 36 V 54 V 9.0 V 60 V​

A 0.50-μF and a 1.4-μF capacitor (C1 and C2, respectively) are connected in series to a...

A 0.50-μF and a 1.4-μF capacitor (C1 and C2, respectively) are connected in series to a 14-V battery. a) Calculate the potential difference across each capacitor. Express your answers using two significant figures separated by a comma. V1 V2 = b) Calculate the charge on each capacitor. Express your answers using two significant figures separated by a comma. Q1 Q2 = c) Calculate the potential difference across each capacitor assuming the two capacitors are in parallel. Express your answers using...

A 2.14 μF capacitor and a 5.62 μF capacitor are connected in series across an 18.0...

A 2.14 μF capacitor and a 5.62 μF capacitor are connected in series across an 18.0 V battery. What voltage would be required to charge a parallel combination of the same two capacitors to the same total energy?

Two capacitors C1 = 4.5 μF, C2 = 19.4 μF are charged individually to V1 =...

Two capacitors C1 = 4.5 μF, C2 = 19.4 μF are charged individually to V1 = 19.7 V, V2 = 7.7 V. The two capacitors are then connected together in parallel with the positive plates together and the negative plates together. - Calculate the final potential difference across the plates of the capacitors once they are connected. - Calculate the amount of charge (absolute value) that flows from one capacitor to the other when the capacitors are connected together. -...

A capacitance C1 = 14.6 μF is connected in series with a capacitance C2 = 5.8...

A capacitance C1 = 14.6 μF is connected in series with a capacitance C2 = 5.8 μF, and a potential difference of 150 V is applied across the pair. a. Calculate the equivalent capacitance. b. What is the charge on C2? c. What is the charge on C1? d. What is the potential difference across C2? e. What is the potential difference across C1? (c25p72) Repeat for the same two capacitors but with them now connected in parallel. f. Calculate...

Two capacitors C1 = 5.6 μF, C2 = 15.1 μF are charged individually to V1 =...

Two capacitors C1 = 5.6 μF, C2 = 15.1 μF are charged individually to V1 = 18.0 V, V2 = 5.7 V. The two capacitors are then connected together in parallel with the positive plates together and the negative plates together. a) Calculate the final potential difference across the plates of the capacitors once they are connected. b) Calculate the amount of charge (absolute value) that flows from one capacitor to the other when the capacitors are connected together. c)...

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...

Two parallel-plate capacitors C1 and C2 are connected in series to a battery. Both capacitors have...

Two parallel-plate capacitors C1 and C2 are connected in series to a battery. Both capacitors have the same plate area of 3.40 cm2 and plate separation of 2.65 mm. However, the first capacitor C1 is filled with air, while the second capacitor C2 is filled with a dielectric that has a dielectric constant of 3.40. The total charge on the series arrangement is 13.8 pC. (a) What is the battery voltage? V (b) What is the potential difference across each...

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...

3. A 1.0 μF capacitor and a 2.0 μF capacitor are connected in different ways across...

3. A 1.0 μF capacitor and a 2.0 μF capacitor are connected in different ways across the terminals of a 12 Volt battery. What is (i) the voltage on each capacitor, (ii) the charge on each capacitor, and (iii) the total energy stored in the capacitors when (a) the capacitors are connected end-to-end (in series)? and (b) the capacitors are connected side-to-side (in parallel)?