A cube of side `a` is placed in a uniform electric field `E = E_(0) hat(i) + E_(0) hat(j) + E_(0) hatk`. Total electric flux passing through the cube would be

A surface element vec(ds) = 5 hat(i) is placed in an electric field vec(E) = 4 hat(i) + 4 hat(j) + 4 hat(k) . What is the electric flux emanting from the surface ?

A cube of edge a is kept on x-axis in a region where electric field varies with distance as E = kx hati . Total electric flux associated with the cube is-

A cube of side l is p laced in a uniform field E, where E=E hati . The net electric flux through the cube is

The potential field of an electric field vec(E)=(y hat(i)+x hat(j)) is

A cube has sides of length L = 0.300 m . It is placed with one corner at the origin ( refer to Fig.2.119).The electric field is not uniform but is given by vec( E) = ( -5.00 NC^(-1)) x hat(i) + (3.00 NC^(-1)) z hat(k) . The total flux passing through the cube is

A thin non-conducting ring or radius a has a linear charge density lambda = lambda_(0) sin phi . A uniform electric field E_(0) hat(i) + E_(0) hat(j) exist in the region . .Net torque acting on ring is given as :

A hemispherical bowl of radius r is placed in uniform electric field E . The electric flux passing through the bowl is

A square of side 'a' is lying in xy plane such that two of its sides are lying on the axis. If an electric field vec(E)=E_(0)xhat(k) is applied on the square. The flux passing through the square is :