An electric field `vecE = vec I Ax` exists in the space, where `A= 10 V m ^(-2).` Take the potential at (10m, 20m ) to be zero. Find the potential at the origin.

An electric field vec(E)=B x hat(i) exists in space, where B = 20 V//m^(2) . Taking the potential at (2m, 4m) to be zero, find the potential at the origin.

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).

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) .

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) .

Assume that an electric field vec(E) = 30 x^(2) hat(i) exists in space. Then the potential differences V_(A) - V_(0) where V_(0) is the potential at the origin and V_(A) , the potential at x = 2m is

An electric field vec E=20y hat j exist in space . The potential at (5 m, 5 m) is taken to be zero. The potential at origin is

Assume that an electric field vecE=30x^2hati exists in space. Then the potential difference V_A-V_O , where V_O is the potential at the origin and V_A the potential at x=2m is:

A uniform field of 8 N/C exists in space in positive x-direction. (a) Taking the potential at the origin to be zero, write an expression for the potential at a general point (x, y, z). (b) At which points, the potential is 160 V ? (c) It the potential at the origin is taken to be 80V, what will be the expression for the potential at a general point ? (d) What will be the potential at the origin if the potential at x = infinity is taken to be zero ?

(A)Two point charges q_1 and q_2 are kept r distance apart in a uniform external electric field vecE . Find the amount of work done in assembling this system of charges. (B) A cube of side 20 cm is kept in a region as shown in the figure. An electric field vecE exists in the region such that the potential at a point is given by V = 10x + 5 , where V is in volt and x is in m. Find the electric field vecE and (ii) total electric flux through the cube.

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.