A parallel palte capacitor is filled by a dielectric whose relative permittively varies with the applied voltage (U) as `epsilon = alpha U` where alpha `= 2V^(-1)`. A similar capacitor with no dielectric is charged to `U_(0) = 78V`. It is then is connected to the uncharged capacitor with the dielectric. Find the final voltage on the capacitors.

parallel plate capacitor is filled by a dielectric whose dielectric constant varies with the applies voltage (V) as K = 2V. A similar capacitor with no dielectric is charged to V_(0)=78 volt.It is then connected to the uncharged capacitor with the dielectric.Find the final voltage on the capacitors

A parallel plate capacitor is filled by a di-electric whose relative permittively varies with the applied voltage according to the law =alpha V , where alpha = 1 per volt. The same (but contiaining no di-electirc) capacitor charged to a voltage V = 156 volt is connected in parallel to the first ''non-linear'' uncharged capacitor. Determine the final voltage V_(f) across the capacitors.

A 20F capacitor is charged to 5V and isolated. It is then connected in parallel with an uncharged 30 F capacitor. The decrease in the energy of the system will be

A parallel plate capacitor is first connected to a constant voltage source. It is then disconnected and ·then immersed in a liqnid dielectric, then:

The capacity of a parallel plate capacitor with no dielectric substance but with a separation is reduced to half and it is filled with a dielectirc substance of value 2.8 . The final capacity of the capacitor is

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 parallel plate capacitor is charged to a certain voltage. Now if the dielectric material (with dielectric constant k ) is removed then the