Electric potential is given by
`V=6x-8xy^(2)-8y+6yz-4z^(2)`
Then electric force acting action on `2C` point charge placed on origin will be

Electric potential is given by V = 6x - 8xy^(2) - 8y + 6yz - 4z^(2) Then electric force acting on 2C point charge placed on origin will be

The electirc potential at a point (x, y, z) is given by V = -x^(2)y - xz^(3) + 4 The electric field vecE at that point is

The electirc potential at a point (x, y, z) is given by V = -x^(2)y - xz^(3) + 4 The electric field vecE at that point is

The electirc potential at a point (x, y, z) is given by V = -x^(2)y - xz^(3) + 4 The electric field vecE at that point is

The electric potential at any point x,y and z in metres is given by V = 3x^(2) . The electric field at a point (2,0,1) is

Ten positively charged particles are kept fixed on the x-axis at points x=10cm, 20cm, 30cm, …, 100cm. The first particle has a charge 1.0xx 10^(-8)C , the second 8xx10^(-8) C, the third 27xx10(-8) C and so on. The tenth particle has a charge 1000xx10^(-8)C. find the magnitude of the electric force acting on a 1 C charge placed at the origin.

The electric potential at a space point P (X, Y, Z) is given as V= x^(2)+y^(2)+z^(2) . The modulus of the electric field at that point is proportional to

If the electric potential in a region is represented as V = 2x + 3y - 4z .Then electric field vector will written as

Potential in the x-y plane is given as V=5(x^(2)+xy) volts. Find the electric field at the point (1, -2).

The potential at any point is given by V = x(y^2 - 4 x^2) . Calculate the cartesian components of the electric field at the point.