In the figure shown, conducting shells A and B have charges Q and 2Q distributed uniformly over and B. Value of `V_(A) - V_(B)` k is `(kQ)/(nR)`. Find `n ( k = (1)/(4 pi in_(0))`

Figure shows two rings having charges Q and - sqrt(5)Q . Find potential difference a and B i.e. (V_(A)-V_(B)) .

Two concentric spherical shells of radii R and 2R have charges Q and 2Q as shown in figure Choose the correct optin (K = (1)/(4 pi epsi_(0)))

In the given figure two semicircular wires are connected which are in and plane respectively. And +2 q_(0) charge is distributed uniformly over it. The magnitude of electric field intensity at the origin is (q_(0))/(2^(n//2) pi^(2)epsi_(0) R^(2)) find n.

Find the electric work done in bringing a charge q from A to B in a sphere of charge Q distributed uniformly throughout its volume. .

Two cententric shells of radii R and 2R have given charge q and -2q as shown in figure in a region r lt R (a) E=0 ,(b) E!=0 ,(c ) V=0 (d) V!=0

Two concentric spherical conducting shells of radii R and 2R carry charges Q and 2Q respectively.Change in electric potential on the outer shell when both are connected by a conducting wire is (k=(1)/(4 pi varepsilon_(0)))

There are four concentric shells A,B, C and D of radii a,2a,3a and 4a respectively. Shells B and D are given charges +q and -q respectively. Shell C is now earthed. The potential difference V_A-V_C is k=(1/(4piepsilon_0))

Three long conducting plates A, B and C having charges +q, -2q , and +q as shown in figure. Here plate A and C are fixed. If the switch S is closed. The middle plate (B) will start moving in

Three conducting spherical shells have charges q,-2q and 3q as shown in figure. Find electric Potential at point P as shown in figure.