Electrostatic field in a region is given by , vecE= (yzhati + zxhatj + xyhatk)V/m , where x,y and z are in m. If electric potential at origin is zero, then potential at (1m,1m, 1m) is

An electric field E = (20hati + 30 hatj) N/C exists in the space. If the potential at the origin is taken be zero, find the potential at (2 m, 2 m) .

The electric field in a region is given by vecE = (A/x^3) hati. Write a suitable SI unit for A. Write an expression for the potential in the region assuming the potential at infinity to be zero.

An electric field E = (20hati + 30 hatj) N/C exists in the space. If thepotential at the origin is taken be zero, find the potential at (2 m, 2 m) .

The gravitational field in a region is given by vec(E) = (4hat(i) + 3hat(j)) N//Kg . The gravitational potential at the points (3m, 0) and (0, 4m). If the potential at the origin is taken to be zero.

Electric field in a region is given by E=(2hati+3hatj-4hatk)V//m . Find the potential difference between points (0, 0, 0) and (1,2,3) in this region.

The gravitational field in a region is given by vecE=-(20Nkg^(-1))(hati+hatj) . Find the gravitational potential at the origin (0,0) in J kg^(-1)

The electric field in a region is given by vecE = (A/x^3) vecI. Write a suitable SI unit for A. Write an experssion for. the potential in the region assuming the potential at. infinity to be zero.

An electric field vecE = vec(i20 + vecj30 ) NC^(-1) exists in the space. If the potential at the origin is taken to be zero find the potential at (2m, 2m).

The electric field in a certain region is given by E=(5hati-3hatj)kV//m . Find the difference in potential V_B-V_A . If A is at the origin and point B is at a. (0,0,5)m, b. (4,0,3) m.

A graph of the x-component of the electric field as a function of x in a region of space is shown in figure. The y- and z-components of the electric field are zero in this region. If the electric potential is 10 V at the origin, then the potential at x = 2.0 m is