A) What is the maximum number of 5.00 microF capacitors that can be connected in parallel with a 4.00 V battery while keeping the total charge stored within the capacitor array below 948 microC?
I know the answer is 47 capacitors for question A
B) If the same number of 5.00 microF capacitors are connected in series with the same 4.00 V battery, how much charge will end up on each capacitor plate?????
1. Ceq= n*C
q= Ceq*V
=>Ceq=2.37^10^-4
=> n=47
2.Ceq= C/47
q= Ceq*V=1/(2350000)
A) What is the maximum number of 5.00 microF capacitors that can be connected in parallel...
What is the maximum number of 6.00 ?F capacitors that can be connected in parallel with a 6.00 V battery while keeping the total charge stored within the capacitor array below 484 ?C? If the same number of 6.00 ?F capacitors are connected in series with the same 6.00 V battery, how much charge will end up on each capacitor plate?
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What is the maximum number of 5.50 uF capacitors that can be connected in parallel with a 6.00 V battery while keeping the total charge stored within the capacitor array below 942 UC? Number If the same number of 5.50 HF capacitors are connected in series with the same 6.00 V battery, how much charge will end up on each capacitor plate? Number
What is the maximum number of 6.00 ?F capacitors that can be connected in parallel with a 6.00 V battery while keeping the total charge stored within the capacitor array below 484 ?C?
5. A parallel combination of two identical 2.0 uF parallel plate capacitors is connected to a 100-V battery. The battery is then removed and the separation between the plates of one of the capacitors is doubled. Find the charge on each capacitor 6. For the circuit shown below, Find: (a) The equivalent capacitance (b) The charge on each capacitor (c) The voltage across each capacitor (d) The total energy stored 0.3 F 10.0V 1.0 uF 0.25 uf
Two air-filled parallel-plate capacitors with capacitances C1 and C2 are connected in series to a battery that has voltage V; C1 = 3.00 μF and C2 = 6.00 μF. The electric field between the plates of capacitor C2 is E02. While the two capacitors remain connected to the battery, a dielectric with dielectric constant K = 4 is inserted between the plates of capacitor C1, completely filling the space between them. After the dielectric is inserted in C1, the electric...
Two capacitors, C1 = 4.92 μF and
C2 = 14.1 μF, are connected in
parallel, and the resulting combination is connected to a 9.00-V
battery.
(a) Find the equivalent capacitance of the combination.
(b) Find the potential difference across each capacitor.
(c) Find the charge stored on each capacitor.
*PLEASE ANSWER ALL PARTS TO A, B, AND C CLEARLY* THANK YOU FOR
YOUR HELP IN ADVANCE!
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