Two concentric 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 conducting shells of radii R and 2R are having charges Q and -2Q respectively.In a region r

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)))

Two concentric spherical shells of radii R and 2R have charges Q and 2Q as shown in figure If we draw a graph between potential V and distance r from the centre, the graph will be like

there are two concentric metallic shells of radii R and 2R, if outer shell is given charge q_1 , then charge on surface of inner shell will be

consider two thin unifromly charged concentric shells of radii r and 2r charges Q and -Q respectively , as shown. Three points A,Band C are marked at distances r/2 , (3r)/2and (5r)/2 respectively from their common centre. If E_(A) E_(B) and E_(C) are magniudes of the electric fields at points A, Band C respectivly ,then

Two concentric spherical conducting shells of radii R and 2R are carrying charges q and 2q, respectively. Both are now connected by a conducting wire. Find the change in electric potential (inV) on the outer shell.

Consider two concentric metalic shell's of radii R and 2R. The inner shell is having charge Q and outer shell is uncharged. If they are connected with a conducting wire. Then,

The figure represents two concentric shells of radii R_(1) and R_(2) and masses M_(1) and M_(2) respectively. The gravitational field intensity at the point A at distance a (R_(1) lt a lt R_(2)) is

Two concentric shells have radii R and 2R charges q_A and q_B and potentials 2V and (3/2)V respectively. Now, shell B is earthed and let charges on them become q_A' and q_B' . Then,

Two uniformly charged concentric spherical shells of radius R and r, are given charges Q_1 and Q_2 respectively. If their potential difference is V, then it will not depends upon: