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iamaelephant
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[SOLVED] Capacitor with 2 dielectrics
A parallel plate capacitor of plate area A and spacing d is filled with two parallel slabs of dielectric of equal thickness with dielectric constants k1 and k2, respectively. What is the capacitance?
You tell me.
I wasn't sure if I could do something simple like take an average of the dielectric constants (although I suspect not). Instead I split the capacitor into two series capacitors and added them in the usual way. Is this allowed? Off the top of my head it seems to be okay, but I'm probably wrong.
In any case, here is my working. This electromagnetic stuff is definitely my weak hand so advice on these types of problems would be great.
Splitting the capacitor into two series capacitors, we can get their capacitances using the equation
<br /> C_1 = \frac{k_1 \epsilon_0 A}{\frac{d}{2}}<br /> = \frac{2k_1 \epsilon_0 A}{d}<br />
<br /> C_2 = \frac{k_2 \epsilon_0 A}{\frac{d}{2}}<br /> = \frac{2k_2 \epsilon_0 A}{d}<br />
\frac{1}{C_t} = \frac{1}{C_1} + \frac{1}{C_2} = \frac{d}{2 k_1 \epsilon_0 A} + \frac{d}{2 k_2 \epsilon_0 A}<br /> = \frac{2 d \epsilon_0 A (k_1 + k_2)}{(2 k_1 \epsilon_0 A)(2 k_2 \epsilon_0 A)}<br />
C_t = \frac{2 \epsilon_0 A k_1 k_2}{d(k_1 + k_2}
Homework Statement
A parallel plate capacitor of plate area A and spacing d is filled with two parallel slabs of dielectric of equal thickness with dielectric constants k1 and k2, respectively. What is the capacitance?
Homework Equations
You tell me.
The Attempt at a Solution
I wasn't sure if I could do something simple like take an average of the dielectric constants (although I suspect not). Instead I split the capacitor into two series capacitors and added them in the usual way. Is this allowed? Off the top of my head it seems to be okay, but I'm probably wrong.
In any case, here is my working. This electromagnetic stuff is definitely my weak hand so advice on these types of problems would be great.
Splitting the capacitor into two series capacitors, we can get their capacitances using the equation
<br /> C_1 = \frac{k_1 \epsilon_0 A}{\frac{d}{2}}<br /> = \frac{2k_1 \epsilon_0 A}{d}<br />
<br /> C_2 = \frac{k_2 \epsilon_0 A}{\frac{d}{2}}<br /> = \frac{2k_2 \epsilon_0 A}{d}<br />
\frac{1}{C_t} = \frac{1}{C_1} + \frac{1}{C_2} = \frac{d}{2 k_1 \epsilon_0 A} + \frac{d}{2 k_2 \epsilon_0 A}<br /> = \frac{2 d \epsilon_0 A (k_1 + k_2)}{(2 k_1 \epsilon_0 A)(2 k_2 \epsilon_0 A)}<br />
C_t = \frac{2 \epsilon_0 A k_1 k_2}{d(k_1 + k_2}