In the figure (Figure 1), each capacitor has 4.00 μF and Vab = 25.0 V Calculate...

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 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 27.0-μF capacitor and a 50.0-μF capacitor are charged by being connected across separate 40.0-V batteries....

A 27.0-μF capacitor and a 50.0-μF capacitor are charged by being connected across separate 40.0-V batteries. (a) Determine the resulting charge on each capacitor. (Give your answer to at least three significant figures.) 27.0-μF capacitor     1.08   mC 50.0-μF capacitor     2    mC (b) The capacitors are then disconnected from their batteries and connected to each other, with each negative plate connected to the other positive plate. What is the final charge of each capacitor? 27.0-μF capacitor     ????? 50.0-μF capacitor     ????? (c)...

A 2.85 μF capacitor is charged to 490 V and a 3.80 μF capacitor is charged...

A 2.85 μF capacitor is charged to 490 V and a 3.80 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? (Enter your answers numerically separated by a comma.) B) What will be the charge on each capacitor? (Enter your answers numerically separated by...

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...

What are the charge on and the potential difference across each capacitor in the figure (Figure...

What are the charge on and the potential difference across each capacitor in the figure (Figure 1) if ΔV = 6.0 V ? Part A Q1 Part B V1 Part C Q2 Part D V2 Part E Q3 Part F V3

A 2.66 ?μF capacitor is charged by being connected across a 12.0-V battery. (a)Find the charge...

A 2.66 ?μF capacitor is charged by being connected across a 12.0-V battery. (a)Find the charge on the capacitor. (b)Find the potential energy of the charged capacitor.

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

Some charge is placed on a capacitor with C1 = 34 μF so that ∆V = 17 V. The capacitor is then attached in parallel to a second capacitor with C2 = 80 μF. What is the voltage across the two capacitors?

A 11.9 μ F capacitor and a 18 μ F capacitor are connected in parallel across...

A 11.9 μ F capacitor and a 18 μ F capacitor are connected in parallel across the terminals of a 6.0 V battery. 1)What is the equivalent capacitance of this combination? 2)What is the potential difference across the 11.9μF capacitor? 3)What is the potential difference across the 18μF capacitor? 4)What is the charge on the 11.9 μF capacitor? 5)What is the charge on the 18 μF capacitor? 6)Find the energy stored in the 11.9 μF capacitor. 7)Find the energy stored...

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​