Answer:
1)
Given, C ( Capacitance)=100microfarad= 100×10^-6 Farad
Voltage, V=120v
Q= C V
Q(charge) =100×10^-6 ×120
Q=12×10^-3 C
2) Given, voltage, V=5.50 v
C(capacitance) =8 pF =8×10^-12 F
Q(charge) =44 ×10^-12 C
3)
Given, C, capacitance=2 microfarad =2×10^-6 F
Charge (Q) =3.10 Microcoulomb= 3.10×10^-6C
Q=C V
V= Q/C =3.10 ×10^-6 /2 ×10^-6
V=1.55 volts
What charge is stored in a 100 μF capacitor when 120 V is applied to it?...
P1: Calculate voltage across and energy stored in each capacitor. 40 μF 20 μF 120 V (+
(a) what voltage (in kV) must be applied to the 8.00 μF capacitor of a heart defibrillator to store 600 נ in it? kV (b) Find the amount (in C) of stored charge.
Find the charge stored by a 200 uF capacitor when 4.0 V is applied.
In the figure a potential difference of V = 120 V is applied across a capacitor arrangement with capacitances C1 = 8.88 UF, C2 = 7.45 pF, and C3 = 12.0 pF. What are (a) charge 43, (b) potential difference V3, and (c) stored energy Uz for capacitor 3, (d) 91, (e) Vu, and (f) U, for capacitor 1, and (g) 92, (h) V2, and (i) U2 for capacitor 2 Cg
(a) What voltage (in kV) must be applied to the 12.0 μF capacitor of a heart defibrillator to store 450 〕 in it? kV (b) Find the amount (in C) of stored charge.
Consider the figure below. C1 0.300 μF (a) Find the charge stored on each capacitor in the figure shown above (C1 = 18.7 μF, C2 = 8.72 μF, and C3 = 0.300 μF) when a 1.69 V battery is connected to the combination e. (b) What energy is stored in each capacitor? E1 = E2 =
In the figure a potential difference V = 120 V is applied across a capacitor arrangement with capacitances C1 = 14.3 µF, C2 = 4.40 µF, and C3 = 4.43 µF. What are (a) charge q3, (b) potential difference V3, and (c) stored energy U3 for capacitor 3, (d) q1, (e) V1, and (f) U1 for capacitor 1, and (g) q2, (h) V2, and (i) U2 for capacitor 2? Chapter 25, Problem 034 In the figure a potential difference V...
Tipler6 24.P.029. A 11.4 μF capacitor and a 17.5 μF capacitor are connected in parallel across the terminals of a 6.0 V battery. (a) What is the equivalent capacitance of this combination? μF (b) What is the potential difference across each capacitor? V (11.4 μF capacitor) V (17.5 μF capacitor) (c) Find the charge on each capacitor. μC (11.4 μF capacitor) μC (17.5 μF capacitor) (d) Find the energy stored in each capacitor. μJ (11.4 μF capacitor) μJ (17.5 μF...
Given a 1.75 μF capacitor, a 3.25 μF capacitor, and a 4.00 V battery, find the charge on each capacitor if you connect them in the following ways. (a) in series across the battery 1.75 μF capacitor μC 3.25 μF capacitor μC (b) in parallel across the battery 1.75 μF capacitor μC 3.25 μF capacitor μC
Given a 3.00 μF capacitor, a 6.00 μF capacitor, and a 3.00 V battery, find the charge on each capacitor if you connect them in the following ways. (a) in series across the battery 3.00 μF = ? capacitor μC 6.00 μF = ?capacitor μC (b) in parallel across the battery 3.00 μF = ?capacitor μC 6.00 μF = ?capacitor μC