CIE A Level Physics復習筆記19.2.2 Capacitor Discharge Equations
The Time Constant
- The time constant of a capacitor discharging through a resistor is a measure of how long it takes for the capacitor to discharge
- The definition of the time constant is:
The time taken for the charge of a capacitor to decrease to 0.37 of its original value
The time constant gives an easy way to compare the rate of change of similar quantities eg. charge, current and p.d.- The time constant is defined by the equation:
Where:
R = resistance of the resistor (?)- C =?capacitance?of the capacitor (F)
The graph of voltage-time for a discharging capacitor showing the positions of the first three time constants
Worked Example
A capacitor of 7 nF is discharged through a resistor of resistance R. The time constant of the discharge is 5.6 × 10-3?s.Calculate the value of R.
Step 1:?Write out the known quantities
Capacitance, C = 7 nF = 7 × 10-9?F
Time constant, τ = 5.6 × 10-3?s
Step 2:?Write down the time constant equation
τ = RC
Step 3:?Rearrange for resistance R
Step 4:?Substitute in values and calculate
Using the Capacitor Discharge Equation
- The?time constant?is used in the exponential decay equations for the current, charge or potential difference (p.d) for a capacitor discharging through a resistor
- These can be used to determine the amount of current, charge or p.d left after a certain amount of time when a capacitor is discharging
- The?exponential decay?of current on a discharging capacitor is defined by the equation:
- Where:
- I = current (A)
- I0?= initial current before discharge (A)
- e = the exponential function
- t = time (s)
- RC = resistance (?) × capacitance (F) = the time constant τ (s)
- This equation shows that the faster the time constant τ, the quicker the exponential decay of the current when discharging
- Also, how big the initial current is affects the rate of discharge
- If I0?is large, the capacitor will take longer to discharge
- Note:?during capacitor discharge, I0?is always larger than I, this is because the current I will always be decreasing
- The current at any time is directly proportional to the p.d across the capacitor and the charge across the?parallel plates
- Therefore, this equation also describes the change in p.d and charge on the capacitor:
- Where:
- Q = charge on the capacitor plates (C)
- Q0?= initial charge on the capacitor plates (C)
- Where:
- V = p.d across the capacitor (C)
- V0?= initial p.d across the capacitor (C)
The Exponential Function?e
- The symbol e represents the exponential constant, a number which is approximately equal to e = 2.718...
- On a calculator it is shown by the button ex
- The inverse function of ex?is ln(y), known as the natural logarithmic function
- This is because, if ex?= y, then x = ln (y)
- The 0.37 in the definition of the?time constant?arises as a result of the exponential constant, the true definition is:
Worked Example
The initial current through a circuit with a capacitor of 620 μF is 0.6 A. The capacitor is connected across the terminals of a 450 ? resistor.Calculate the time taken for the current to fall to 0.4 A.
Step 1:?Write out the known quantities
Initial current before discharge, I0?= 0.6 A
Current, I = 0.4 A
Resistance, R = 450 ?
Capacitance, C = 620 μF = 620 × 10-6?F
Step 2:?Write down the equation for the exponential decay of current
Step 3:?Calculate the time constant
τ = RC
τ = 450 × (620 × 10-6) = 0.279 s
Step 4:?Substitute into the current equation
Step 5:?Rearrange for the time?t
The exponential can be removed by taking the natural log of both sides:
Exam Tip
Make sure you’re confident in rearranging equations with natural logs (ln) and the exponential function (e). To refresh your knowledge of this, have a look at the AS Maths revision notes on Exponentials & Logarithms
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