Capacitor in a Parallel Circuit

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PhotonTrail
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Homework Statement



I'm not sure how to put this in words, but I shall try. Alternatively, I've attached an image. It's hand-drawn, but I hope it's legible enough.

Imagine a circuit drawn in the shape of a rectangle, with a single resistor ##R_1## on the top side, plus a DC cell ##\epsilon_2## and a second resistor ##R_3## on the bottom side. Now connect the left and right sides of the rectangle with a horizontal line in the middle. This portion of the circuit contains the following: a capacitor ##C_1##, a second DC cell ##\epsilon_1##, and a third resistor ##R_2##.

Question: What are the currents at every point in the circuit?


Homework Equations



None.


The Attempt at a Solution



I would say that the portion of the circuit with the capacitor has no current flowing through, i.e. ##I_2=0##. I originally thought too that ##I_1## and ##I_3## are equal to zero too, because I found it difficult to accept that there will be current flowing in the other parts of the circuit if there is no potential difference across the middle branch.

Am I mistaken in thinking that ##I_2## is zero? If I am not, am I wrong in assuming that the potential difference between the left and right sides of the middle branch is zero? If I am still not, then why do the top and bottom branches have currents flowing? How do the potential differences work out?

Many thanks for any assistance!
 

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PhotonTrail said:

Homework Statement



I'm not sure how to put this in words, but I shall try. Alternatively, I've attached an image. It's hand-drawn, but I hope it's legible enough.

Imagine a circuit drawn in the shape of a rectangle, with a single resistor ##R_1## on the top side, plus a DC cell ##\epsilon_2## and a second resistor ##R_3## on the bottom side. Now connect the left and right sides of the rectangle with a horizontal line in the middle. This portion of the circuit contains the following: a capacitor ##C_1##, a second DC cell ##\epsilon_1##, and a third resistor ##R_2##.

Question: What are the currents at every point in the circuit?

Homework Equations



None.

The Attempt at a Solution



I would say that the portion of the circuit with the capacitor has no current flowing through, i.e. ##I_2=0##. I originally thought too that ##I_1## and ##I_3## are equal to zero too, because I found it difficult to accept that there will be current flowing in the other parts of the circuit if there is no potential difference across the middle branch.

Am I mistaken in thinking that ##I_2## is zero?
You are not mistaken about this. The current, ##\ I_2\,,\ ## is zero.

... Well, it's zero if the capacitor is not charging or discharging.


If I am not, am I wrong in assuming that the potential difference between the left and right sides of the middle branch is zero?
Yes. You are wrong about this. That ##\ I_2=0\ ## only means that the voltage drop across R3 is zero. The is a potential difference across ##\ \varepsilon_1\ ## and also across the capacitor.

If I am still not, then why do the top and bottom branches have currents flowing? How do the potential differences work out?

Many thanks for any assistance!
 
SammyS said:
You are not mistaken about this. The current, ##\ I_2\,,\ ## is zero.

... Well, it's zero if the capacitor is not charging or discharging.

Forgot to mention that it's in steady state, sorry!


SammyS said:
Yes. You are wrong about this. That ##\ I_2=0\ ## only means that the voltage drop across R3 is zero. The is a potential difference across ##\ \varepsilon_1\ ## and also across the capacitor.

Ahh I see it now. What an embarrassing blunder. Thanks a bunch! :)