A capacitor of capacitance and potential has energy . It is connected to another capacitor of capacitance and potential . Then the loss of energy is , where is:
- A
- B
- C
- D
A capacitor of capacitance and potential has energy . It is connected to another capacitor of capacitance and potential . Then the loss of energy is , where is:
Correct answer:B
Standard Method
Given: First capacitor has capacitance , potential , and energy . Second capacitor has capacitance and potential .
Find: The value of if the loss of energy is .
Use conservation of charge after connecting the capacitors in parallel and then compare initial and final energies.
Initial energy of the first capacitor:
Initial energy of the second capacitor:
So, total initial energy is
Initial charges are
Hence total charge is
Total capacitance after parallel connection is
Therefore common potential is
Final energy of the system is
Thus loss of energy is
Now, since
we get
Comparing with
we obtain
Therefore, the correct option is B.
Energy Comparison Approach
Given: Two isolated capacitors, one with and the other with .
Find: The value of in the expression for energy loss.
The key idea is that charge is conserved, but electrostatic energy decreases after redistribution.
So the loss is , which means .
Therefore, the correct option is B.
Using only the energy of the first capacitor as the total initial energy is incorrect because both capacitors are initially charged. Always add the initial energies of both capacitors before calculating the loss.
Finding the final potential without conserving total charge is wrong. After connection, the common potential must be obtained from .
Comparing the energy loss directly with without using leads to the wrong value of . First rewrite the loss in terms of the given reference energy .
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