The potential field depends on x and y coordinates as `V=(x^2-y^2)` Corresponding electric field lines in `x-y` plane are as

The electric potential at any point in 3 dimensional co-ordinate (x,y, z) space is V = 4x^2 volt. The electric field at (1m, 0m, 2m) point in V//m will be

The electric potential in a region is represented as, v=2x+3y-z The electric field strength is

In an electric field, the potential V(x), depending only on the x-coordinate, is given by V(x) = ax -bx^(3) , where a and b are constants, find out the points on the x -axis where the electric field intensity would vanish.

The electric potential V at any point (x, y, z) all in meters in space is given by V = 4x^(2)V . The electric field at the point (1,0,2) in V cdot m^(-1) is

The electric potential V(x) in an electric field depends only on x and V(x) = ax - bx^(3) where a and b are constants. Where on the x-axis will electric field intensity be zero?

If potential (in volts) in a region is expressed as V(x, y, z) = 6 xy- y + 2yz, the electric field (in N//C ) at point (1,1,0) is

On the X-Y plane two point charges "+q and -q are placed at positions (0, L) and (0,-L) respectively. Find an expression for the intensity of the electric field at a point (0, y) where y >> L . Express the electric field in terms of the dipole moment so formed.

In a certain place, the electric potential changes according to the relation V = 3x + 2y^(2) , V is measured in volt and x,y in metre. What is the electric field intensity at the point (3,1)?

The electric potential at a point (x, y, z) is given by V = -x^(2)y - xz^(3) +4 . Find the intensity of electric field vec(E ) at that point.

What is potential gradient? The electric potential is found to depend on X only and is given by V(x) = ax - bx^2 , where a and b are constants. Find the positions on the X - axis where electric field intensity is zero.