If `C_(AB)` (equivalent ) = `(C ) /(2)` and capacitance of all the capacitors are C in vacuum without dielectric . Find the relation between `k_(1).k_(2).k_(3)`

Find the equivalent capacitance between A and B. All the capacitors have capacitance C.

Find the equivalent capacitance between A and B. All the capacitors have capacitance C.

The equivalent capacitance of three capacitors of capacitance C_(1):C_(2) and C_(3) are connected in parallel is 12 units and product C_(1).C_(2).C_(3) = 48 . When the capacitors C_(1) and C_(2) are connected in parallel, the equivalent capacitance is 6 units. then the capacitance are

In the figure a capacitor is filled with dielectrics K_(1) , K_(2) and K_(3) . The resultant capacitance is

A parallel plate capacitor of area A, plate separation d and capacitance C is filled with four dielectric materials hving dielectric constants K_(1), K_(2), K_(3) and K_(4) as shown in the figure below. If a single dielectric material is to be used to have the same capacitance c in this capacitor, then its dielectric constant K is given by

A parallel plate capacitor has a dielectric slab of dielectric constant K between its plates that covers 1//3 of the area of its plates, as shown in the figure. The total capacitance of the capacitor is C while that of the portion with dielectric in between is C_1 . When the capacitor is charged, the plate area covered by the dielectric gets charge Q_1 and the rest of the area gets charge Q_2 . The electric field in the dielectric is E_1 and that in the other portion is E_2 . Choose the correct option/options, ignoring edge effects.

Obtain an expression for equivalent capacitance when three capacitors C_1, C_2 and C_3 are connected in series.

Deduce an expression for equivalent capacitance C when three capacitors C_(1), C_(2) and C_(3) are connected in parallel.

Find the capacitance between A and B if three dielectric slabs of dielectric constants K_(1) area A _(2) and thickness d_(2) ) are inserted between the plates of a parallel late capacitor of plate area A. (Given that the distance between the two plates is d_(1)=d_(2)+d_(2) .) .

Two identical parallel plate capacitors, of capacitance C each, have plates of area A, separated by a distance d. The space between the plates of the two capacitors, is filled with three dielectrics, of equal thickness and dielectric constants K_(1),K_(2) and K_(3) . The first capacitor is filled as shown in fig. I, and the second one is filled as shown in fig. II. If these two modified capacitors are charged by the same potential V, the ratio of the energy stored in the two, would be ( E_(1) refers to capacitor (I) and E_(2) to capacitor (II)):