A capacitor of capacitance `C_(0)` is charged to a patential `V_(0)` and then isolated. A small capacitor C is then charged from `C_(0)`, discharged and charge again, the process being is decreased to V. Find the value of C.

A capacitor of capacitance C_(o) is charged to a potential V and then isolated. A small capacitor C is then charged from C_(o) , discharged and charged again, the process being repeated n times. Due to this, potential of the large capacitor is decreased to V . Find the capacitance of the small capacitor :

A capacitence of C_(0) is charged to a potential V_(0) and then isolated. A small cpacitor C is then charged from C_(0) , discharged and charged again, the process bing repeated n times. Due to this, potential of the large capacitor is decreased to V . find the capacitance of the small capacitor. is it possible to remove charge on C_(0) completely in this way?

A capacitor of capacitance C_(0) is charged to a voltage V_(0) and then isolated. An uncharged capacitor C is then charged from C_(0) , discharged and charged again , the process is repeated n times. Due to this, potential of the C_(0) is decreased to V, then value of C is :

A capacitor of capacitance C_0 is charged to potential V_0 . Now it is connected to another uncharged capacitor of capacitance C_0/2 . Calculate the heat loss in this process.

A capacitor of capacitance C_(1) is charged to a potential difference V and then connected with an uncharged capacitor of capacitance C_(2) a resistance R. The switch is closed at t = 0. Choose the correct option(s):

A capacitor or capacitance C_(1) is charge to a potential V and then connected in parallel to an uncharged capacitor of capacitance C_(2) . The fianl potential difference across each capacitor will be

A capacitor of capacitance C is charged to a potential differece V_(0) . The terminals of the charged capacitor are then connected to those of an uncharged capacitor of capacitance C//2 . a. Compute the original charge of the system. b. Find the final potential differce across each capacitor. c. Find the final energy of the system. d. Calculate the decrease in energy when the capacitors are connected. e. Where did the ''lost'' energy go?

A capacitor of capacitance C_(1) is charged to a potential V_(1) while another capacitor of capacitance C_(2) is charged to a potential difference V_(2) . The capacitors are now disconnected from their respective charging batteries and connected in parallel to each other . (a) Find the total energy stored in the two capacitors before they are connected. (b) Find the total energy stored in the parallel combination of the two capacitors. (c ) Explain the reason for the difference of energy in parallel combination in comparison to the total energy before they are connected.

A capacitor of capacitance C is charged to a potential V . The flux of the electric field through a closed surface enclosing the capacitor is