The space between the plates of a parallel plate capacitor is filled with a dielectric whose dielectric constant varies with distance as per the relation: |
\[K(x)={{K}_{o}}+\lambda x\] (\[\lambda =\] a constant) |
The capacitance C, of the capacitor, would be related to its vacuum capacitance Co for the relation: [JEE ONLINE 12-04-2014] |
A) \[C=\frac{\lambda d}{\ln (1+{{K}_{o}}\lambda d)}{{C}_{o}}\]
B) \[C=\frac{\lambda }{d.ln(1+{{K}_{o}}\lambda d)}{{C}_{o}}\]
C) \[C=\frac{\lambda d}{ln(1+\lambda d/{{K}_{o}})}{{C}_{o}}\]
D) \[C=\frac{\lambda }{d.ln(1+{{K}_{o}}/\lambda d)}{{C}_{o}}\]
Correct Answer: C
Solution :
[c] The value of dielectric constant is given as, |
\[K={{K}_{0}}+\lambda x\]And, \[V=\int\limits_{0}^{d}{Edr}\] |
\[V=\int\limits_{0}^{d}{\frac{\sigma }{K}dx}\] |
\[=\sigma \int\limits_{0}^{d}{\frac{1}{({{K}_{0}}+\lambda x)}dx}\] |
\[=\frac{\sigma }{\lambda }\left[ \ln \left( {{K}_{0}}+\lambda d \right)-\ln {{K}_{0}} \right]\] |
\[=\frac{\sigma }{\lambda }\ln \left( 1+\frac{\lambda d}{{{K}_{0}}} \right)\] |
Now it is given that capacitance of vacuum \[={{C}_{0}}.\] |
Thus, \[C=\frac{Q}{V}\]\[=\frac{\sigma .s}{v}\] (Let surface area of plates = s) |
\[=\frac{\sigma .s}{\frac{\sigma }{\lambda }\ln \left( 1+\frac{\lambda d}{{{K}_{0}}} \right)}\] |
\[=s\lambda .\frac{d}{d}\frac{1}{\ln \left( 1+\frac{\lambda d}{{{K}_{0}}} \right)}\](\[\because \] in vacuum e0 =1) |
\[c=\frac{\lambda d}{\ln \left( 1+\frac{\lambda d}{{{K}_{0}}} \right)}.{{C}_{0}}\]\[\left( \text{here,}\,{{C}_{0}}=\frac{s}{d} \right)\] |
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