RC circuit - Capacitor discharge

AI Thread Summary
When a capacitor discharges, the potential difference across its plates equals that across the resistor. The equation governing this process is derived from Kirchhoff's Second Law, which states that the sum of voltages in a closed loop must equal zero. The correct expression for charge over time is q(t) = Q_0 exp(-t/RC), indicating the need for a negative sign in the original equation. The discussion highlights that during discharge, dq/dt is negative, leading to a contradiction if not properly accounted for. Understanding these principles is crucial for accurately analyzing RC circuits.
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When a capacitor discharges, the potential difference between its plates and the resistor's terminals is the same. Hence,

\frac{Q}{C}=R \frac{dq}{dt}
Solving this equation we get

q(t)= Q_{0} exp \frac{t}{RC}

Obviously, this isn't the solution. It is actually q(t)= Q_0 exp \frac{-t}{RC}. So, I'm missing a minus sign on the original equation.

But why should it be there?
 
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According to Kirchoff's Second Law, the sum of the voltages is equal to zero. R(dQ/dt) + (Q/C) = 0, therefore you need -R(dQ/dt) = (Q/C). I apologize for the lack of proper script.
 
Thank you.
Didn't know such laws.
 
If the capacitor discharges, then dq/dt is negative, so according toyour originial equation, Q/C which is positive equals something negative
 

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