At any point `(x, 0, 0)` the electric potential V is `((1000)/(x)+(1500)/(x^(2))+(500)/(x^(3)))` volt, then electric field intensity at x = 1 m is

The electric potential at a point (x,0,0) is given by V=[(1000)/(x)+(1500)/(x^(2))+(500)/(x^(3))] "then the electric field at" x=1 m is (in volt//m)

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

Electric potential V in space as a function of cartesian co-ordinates is given by V=(1)/(x)+(1)/(y) +(1)/(z) . Then find electric field intensity at (1, 1, 1)

The electric potential V is givne as a function of distance x (metre) by V = (5 x^(2) + 10x - 9) volt. Value of electric field at x = 1 is

The electric potential V is givne as a function of distance x (metre) by V = (5 x^(2) + 10x - 9) volt. Value of electric field at x = 1 is

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

Electric potential in a region is varying according to the relation V = (3x^(2))/(2) - (y^(2))/(4) , where x and y are in metre and V is volt, Electric field intensity (in N/C) at a point (1 m, 2 m ) is

The electric potential in a region is represented as V=2x+3y-z obtain expression for electric field strength.