A charge `q = -2.0 muC` is placed at origin. Find the electric field at `(3 m, 4 m, 0)`.

A point charge q = - 8.0 nC is located at the origin. Find the electric field vector at the point x = 1.2 m, y = -1.6 m.

As charge q=1muC is placed at point (1m,2m,4m) . Find the electric field at point P(0,-4m,3m)

A point charge q is placed at the origin . How does the electric field due to the charge very with distance r from the origin ?

A point charge of 100mu C is placed at 3 hat i+4 hat j m . Find the electric field intensity due to this charges at a point located at 9 hat i+12 hat j m .

There exists a uniform electric field E =4 xx 10^(5) Vm^(-3) directed along negative x-axis such that electric potential at origin is zero. A charge of - 200 mu C is placed at origin and a charged of + 200 mu C is placed at a (3 m, 0) . The electrostatic potential energy of the system is

A charge q_(1) = 2.00 mu C is located at the origin , and a charge q_(2) = - 6.00 mu C is located at ( 0,3.00 ) m . (a) Find the total electric potential due to these charges at the point P hose coordinates are ( 4.00,0) m . ( b) Find the change in potential energy of the system of two charges plus a charge q_(3)= 3.00 muC as the latter charge moves from infinity to point P .

Two charges +- 10 muC are placed 5xx10^(-3) m apart. Determine the electric field at a point Q, 0*15m away from O, on a line passing through O and normal to the axis of the dipole.

Two point charges Q and -3Q are placed at some distance apart. If the electric field at the location of Q is vec (E ) , the field at the location of - 3Q is

A charge q=10muC is distributed uniformly over the circumference of a ring of radius 3m placed on x-y placed with its centre art origin. Find the electric potential at a point P(0,0,4m)

A charge q=10muC is distributed uniformly over the circumference of a ring of radius 3m placed on x-y placed with its centre art origin. Find the electric potential at a point P(0,0,4m)