Decay in Energy in an RC circuit?

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Homework Help Overview

The discussion revolves around determining the time at which a capacitor in an RC circuit has lost 50% of its energy. The problem involves concepts from circuit theory, specifically related to capacitors, energy storage, and exponential decay in electrical components.

Discussion Character

  • Exploratory, Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • Participants explore the relationship between charge decay and energy loss in the capacitor. There are discussions about using different equations for energy and charge, and how to connect these to find the time for energy decay.

Discussion Status

Participants are actively engaging with the problem, questioning how to relate the energy stored in the capacitor to the decay equations provided. Some have suggested methods to approach the problem, while others express confusion about the connections between the equations and the physical concepts involved.

Contextual Notes

There is a focus on the initial conditions provided, such as voltage, capacitance, and resistance, as well as the need for clarity on how to apply the energy equations in the context of the RC circuit's behavior over time.

oh.rry21
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Homework Statement



They want us to find T, time, when the capacitor has lost 50% of its energy. They give us voltage, capacitance, and resistance.



Homework Equations



I=I_o(e^(-t/RC))
Q=Q_o(e^(-t/RC))

Potential Energy = Q^2/2C

The Attempt at a Solution



I have no idea how to relate charge/current decay to energy in an RC circuit. Does anyone have any ideas? :(
 
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There's an additional formula for the energy stored in a capacitor in terms of the capacitance and the voltage.
 
but even if i had that equation...how would i use it in relation to the RC equations? just because i have an energy equation in terms of capacitance and voltage doesn't mean i can find the time it takes for it to decay to 50%of its original energy.
 
The charge on the capacitor is changing, in which the U = Q^2/2C. Since C is constant, the only variable you need to take account for is Q. If Q_o is the initial charge (and largest charge), it contributes to the highest potential energy, U_o of the capacitor. Half of U_o occors when about 1/sqr(2) of Q_o is left, in which sqr() is square root. Using Q=Q_o(e^(-t/RC)) for Q = (1/sqr(2)*Q_o, solve for t.
 
wait how did you know that

U_o is 1/sq(2) of Q_o?

i know there's easy algebra involved x_x haha but i don't see how you got there
 
He used E = Q^2/2C to find the energy at t=0 when the capacitor had a charge Q_o. that is simply E = Q_o^2/2C.
then used the same equation to get the charge of the capacitor when it has half that energy. (1/2)E = (1/2)(Q_o^2/2C) = Q^2/2C.
 

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