Concept explainers
(a)
The equivalent capacitance for the network given.
(a)
Answer to Problem 28PQ
The equivalent capacitance of the combination is
Explanation of Solution
Write the formula for equivalent capacitance of capacitors in series.
Here,
Write the formula for equivalent capacitance of capacitors in parallel.
Here,
The capacitor
Write the formula for the resultant of
Here,
The capacitance
Write the formula for the equivalent capacitance of the given combination.
Here,
Solve the above equation to get expression for
Conclusion:
Substitute
The equivalent capacitance of the combination is
(b)
The charge stored in each of the capacitors.
(b)
Answer to Problem 28PQ
The charge on capacitor
Explanation of Solution
The capacitors in series
Write the formula for the charge on equivalent capacitor.
Here,
Write the formula for the voltage across capacitor
Here,
Write the formula for the charge across
Here,
Write the formula for the charge across
Here,
Conclusion:
Substitute
Substitute
Substitute
Substitute
The charge on capacitor
(c)
The voltage across each of the capacitors.
(c)
Answer to Problem 28PQ
The voltage across
Explanation of Solution
The capacitors in series
Write the formula for the charge on equivalent capacitor.
Here,
Write the formula for the voltage across capacitor
Here,
Write the formula for the voltage across
Here,
Conclusion:
Substitute
Substitute
Substitute
The voltage across
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Chapter 27 Solutions
Physics for Scientists and Engineers: Foundations and Connections
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- Consider an infinitely long network with identical capacitors arranged as shown in Figure P27.82. Determine the equivalent capacitance of such a network. Each capacitor has a capacitance of 1.00 F.arrow_forwardThree capacitors having capacitances 8.4, 8.4, and 4.2 F are connected in series across a 36.0-V potential difference, (a) What is the total energy stored in all three capacitors? (b) The capacitors are disconnected from the potential difference without allowing them to discharge. They are then reconnected in parallel with each other with the positively charged plates connected together. What is the total energy now stored in the capacitors?arrow_forward(a) Find the equivalent capacitance between points a and b for the group of capacitors connected as shown in Figure P20.44. Take C1 = 5.00 F, C2 = 10.0 F, and C3 = 2.00 F. (b) What charge is stored on C3 if the potential difference between points a and b is 60.0 V? Figure P20.44arrow_forward
- Three capacitors having capacitances of 8.40, 8.40, and 4.20F , respectively, are connected in series across a 36.0-V potential difference. (a) What is the charge on the 4.20F capacitor? (b) The capacitors are disconnected from the potential difference without allowing them to discharge. They are then reconnected in parallel with each other with the positively charged plates connected together. What is the voltage across each capacitor in the parallel combination?arrow_forward(a) How much charge is on each plate of a 4.00-F capacitor when it is connected to a 12.0-V battery? (b) If this same capacitor is connected to a 1.50-V battery, what charge is stored?arrow_forwardFor the four capacitors in the circuit shown in Figure P27.30, CA = 1.00 F, CB = 4.00 F, CC = 2.00 F, and CD = 3.00 F. What is the equivalent capacitance between points a and b? Figure P27.30arrow_forward
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