Answer:
A) q_o = 0.001 C
B) I = 0.001•e^(-t)
C) V_c = 1000e^(-t)
D) V_r = 1000e^(-t)
E) P = e^(-2t) watts
Explanation:
A) We are given;
Initial stored energy; U_o = 0.5 J
Capacitance; C = 1.0μF = 1 × 10^(-6) F
To find the charge, we will use the formula for energy in capacitors which is given by;
U = q²/2C
Thus, since we are dealing with initial energy, U is U_o and q is q_o
Making q the subject, we have;
q_o = √2CU_o
q_o = √(2 × 1 × 10^(-6) × 0.5)
q_o = 0.001 C
B) The charge as a function of time is expressed as;
q = q_o•e^(-t/RC)
Now the current is gotten by differentiating the charge function. Thus;
I = (q_o/RC)•e^(-t/RC)
Where;
R is Resistance = 1.0MΩ = 1 × 10^(6) Ω
C is capacitance = 1 × 10^(-6) F
(q_o/RC) is the initial current = 0.001/(1 × 10^(6) × 1 × 10^(-6))
(q_o/RC) = 0.001 A
Thus;
I = 0.001•e^(-t/(1 × 10^(6) × 1 × 10^(-6)))
I = 0.001•e^(-t)
C) Formula for potential difference across the capacitor is;
V_c = IR
I = 0.001•e^(-t)
R = 1 × 10^(6) Ω
Thus;
V_c = 1 × 10^(6) × 0.001•e^(-t)
V_c = 1000e^(-t)
D) Potential difference across the resistor will be the same as that across the capacitor because the resistor is connected in parallel to the capacitor.
Thus;
V_r = V_c = 1000e^(-t)
E) rate at which thermal energy is produced is basically the power.
Thus;
P = (V_r)²/R
P = (1000²e^(-2t))/1 × 10^(6)
P = e^(-2t) watts
