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The capacitor is initially uncharged. When the switch is moved to position \(1\), electrons move from the negative terminal of the supply to the lower plate of the capacitor. This movement of charge is opposed by the resistor \(R\), so the initial current in the circuit is \(I= \frac{E}{R}\)

• the charging current decreases from an initial value of \(\frac {E}{R}\) to zero
• the potential difference across the capacitor plates increases from zero to a maximum value of \(E\), when the capacitor is fully charged
• at all times the sum of the potential difference across the capacitor and the potential difference across the resistor equals the EMF of the supply
• the potential difference across the resistor (given by \({V_R}= IR\)) decreases from an initial value of \(E\) to zero when the capacitor is fully charged

When the switch is moved to position \(2\), electrons move from the lower plate through the resistor to the upper plate of the capacitor.

• the discharging current decreases from an initial value of \(- \frac {E}{R}\) to zero
• the potential difference across the capacitor plates decreases from \(E\) to zero, when the capacitor is fully discharged
• the potential difference across the capacitor is always equal to the potential difference across the resistor
• the potential difference across the resistor (given by \({V_R}= IR\)) decreases from an initial value of \(E\) to zero when the capacitor is fully discharged