The grid represents a region in space containing a uniform electric field (each square of size `1m xx 1m`). If potentials at point O, A, B, C, D, E, F, G, H are respectively `0, -1, -2, 1, 2, 0, -1, 1` and 0 volts find the electric field intensity.

A uniform electric field exists in x-y plane. The potential of points A (-2m, 2m), B(-2m, 2m) and C(2m, 4m) are 4V, 16 V and 1 2 V respectively. The electric field is

An electron traveling in a uniform electric field passes from a region of potential V_1 to a region of higher potential V_2 . Then

Two point charges 3 muC and 2.5 muC are placed at point A (1, 1, 2)m and B (0, 3, -1)m respectively. Find out electric field intensity at point C(3, 3, 3)m.

(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.

In a uniform electric field, the potential is 10V at the origin of coordinates , and 8 V at each of the points (1, 0, 0), (0, 1, 0) and (0, 0, 1). The potential at the point (1, 1,1 ) will be .

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

A uniform electric field is along x-axis. The potential difference V_(A)-V_(B)=10 V is between two points A (2m, 3m) and (4m, 8m). Find the electric field intensity.

The potential of the electric field produced by point charge at any point (x, y, z) is given by V = 3x^(2) + 5 , where x ,y are in are in metres and V is in volts. The intensity of the electric field at (-2,1,0) is :

A large charged metal sheet is placed in a uniform electric field, perpendicular to the electric field lines. After placing the sheet into the field, the electric field on the left side of the sheet is E_1 = 5 xx 10^5 Vm^(-1) and on the right it is E_2 = 3 xx 10^5 V m^(-1) . The sheet experiences a net electric force of 0.08 N. Find the area of one face of the sheet. Assume the external field to remain constant after introducing the large sheet. Use (1/(4piepsilon_0)) = 9 xx 10^(9) Nm^(2)C^(-2)

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