The diagram below shows a circuit used to charge a capacitor.
The power supply has electromotive force (e.m.f.) 10 V and negligible internal resistance. The capacitor has capacitance C and the resistor has resistance R. The switch is closed at time t = 0. The table below shows potential difference V across the resistor at various values of time t.
V / V | 10 | 6.3 | 5.0 | 3.7 |
t / s | 0 | 2.8 | 4.2 | 6.0 |
What is the product C × R for this circuit?
0 s
2.8 s
4.2 s
6.0 s
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A capacitor discharges through a resistor. At time t = 0 the potential difference V across the capacitor is V0. At time t = 2.0 s, V = 0.90 V0.
Which statement is not correct?
At t = 4.0 s, V = 0.81 V0.
The capacitor is fully discharged after t = 10 s.
The potential difference across the resistor is the same as that for the capacitor when the capacitor has potential difference 0.5V0.
The potential difference V decreases exponentially with time t.
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A student is modelling the decay of charge for a capacitor discharging through a resistor using the equation format('truetype')%3Bfont-weight%3Anormal%3Bfont-style%3Anormal%3B%7D%3C%2Fstyle%3E%3C%2Fdefs%3E%3Cline%20stroke%3D%22%23000%22%20stroke-linecap%3D%22square%22%20stroke-width%3D%221%22%20x1%3D%222.5%22%20x2%3D%2229.5%22%20y1%3D%2219.5%22%20y2%3D%2219.5%22%2F%3E%3Ctext%20font-family%3D%22math17daed61c5b0df1056b43c7eb17%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2210.5%22%20y%3D%2214%22%3E%26%23x2206%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22Arial%22%20font-size%3D%2214%22%20font-style%3D%22italic%22%20text-anchor%3D%22middle%22%20x%3D%2222.5%22%20y%3D%2214%22%3EQ%3C%2Ftext%3E%3Ctext%20font-family%3D%22math17daed61c5b0df1056b43c7eb17%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2214.5%22%20y%3D%2235%22%3E%26%23x2206%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22Arial%22%20font-size%3D%2214%22%20font-style%3D%22italic%22%20text-anchor%3D%22middle%22%20x%3D%2223.5%22%20y%3D%2235%22%3Et%3C%2Ftext%3E%3Ctext%20font-family%3D%22math17daed61c5b0df1056b43c7eb17%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2244.5%22%20y%3D%2224%22%3E%3D%3C%2Ftext%3E%3Ctext%20font-family%3D%22Arial%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2262.5%22%20y%3D%2224%22%3E%26%23x2013%3B%3C%2Ftext%3E%3Ctext%20font-family%3D%22Arial%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2272.5%22%20y%3D%2224%22%3E0%3C%2Ftext%3E%3Ctext%20font-family%3D%22math17daed61c5b0df1056b43c7eb17%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2278.5%22%20y%3D%2224%22%3E.%3C%2Ftext%3E%3Ctext%20font-family%3D%22Arial%22%20font-size%3D%2214%22%20text-anchor%3D%22middle%22%20x%3D%2285.5%22%20y%3D%2224%22%3E2%3C%2Ftext%3E%3Ctext%20font-family%3D%22Arial%22%20font-size%3D%2214%22%20font-style%3D%22italic%22%20text-anchor%3D%22middle%22%20x%3D%2294.5%22%20y%3D%2224%22%3EQ%3C%2Ftext%3E%3C%2Fsvg%3E){kind=small}
.
The student decides to use ∆t = 0.5 s. The initial charge on the capacitor is 1000 μC.
Part of the modelling spreadsheet from the student is shown below.
t / s | Charge Q left on capacitor at time t / μC | Charge ∆Q decaying in the next 0.5 s / μC |
0 | 1000 | 100 |
0.5 | 900 |
|
1.0 |
|
|
1.5 |
|
|
What is the value of Q in μC at t = 1.5 s?
700
720
729
800
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A capacitor discharges through a resistor. At time t = 0, the charge stored by the capacitor is 600 μC. The capacitor loses 5.0% of its charge every second.
What is the charge left on the capacitor at time t = 4.0 s?
111 μC
120 μC
480 μC
489 μC
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A capacitor is discharged through a resistor.
The capacitor is fully charged at time t = 0. The time constant of the circuit is 10 s. The switch is closed at time t = 0. The current in the resistor is 
.
Which row is correct?
| Current | Current |
A | maximum | 0 |
B | maximum | 37% of the current at t = 0 |
C | 0 | 63% of the current at t = ∞ |
D | 0 | 37% of the current at t = ∞ |
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A capacitor is charged through a resistor.
The cell has e.m.f. 1.50 V and negligible internal resistance. The capacitor is initially uncharged. The time constant of the circuit is 100 s. The switch is closed at time t = 0. What is the potential difference across the capacitor at time t = 200 s?
0.20 V
0.55 V
0.95 V
1.30 V
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A capacitor is charged through a resistor.
The cell has electromotive force (e.m.f.) 1.50 V and negligible internal resistance. The time constant of the circuit is 10 s. The switch is closed at time t = 0. At time t, the potential difference across the resistor is 0.60 V.
Which expression is correct?
0.60 = 1.50e–0.10t
0.90 = 1.50(e–10t − 1)
0.60 = 1.50e–10t
0.60 = 1.50(1–e–0.10t)
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at 
= 0