The diagram shows three infinitely long uniform line charges placed on the `X, Y` and ` Z` axis . The work done in moving a unit positive charge from (1,1,1) to (0 , 1,1,) is equal to
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An infinite line of charge lamda per unit length is placed along the y-axis. The work done in moving a charge q from A(a,0) to B (2a,0) is

For an infinite line of charge having linear charge density lambda lying along x-axis the work done in moving a charge q form C to A along CA is

Find the electric field vector at P (a,a,a) due to three infinitely long lines of charges along the x-, y- and z-axis, respectively. The charge density i.e. charge per unit length of each wire is (lambda) ,

The arc AB with the centre C and the infinitely long wire having linear charge density lambda are lying in the same place. The minimum amount of work to be done to move a point charge q_(0) from point A to B through a circuit path AB of radius a is equal to

A dipole of 2muC charges each, consists of the positive charge at the point P (1, -1) and the negative charge is placed at the point Q(-1, 1). The work done in displacing a charge of +1muC from point A(-3,-3) to B (4, 4) is

When the positively charged hanging pendulum bob is made fixed, the work done in slowly shifting a unit positive charge from infinity to P is V. If the pendulum is free to move, the corresponding work done id V' . Then.

What is the work done in moving a test charge q through a distance of 1 cm along the equatorial axis of an electric dipole ?

A charge of 5 mu C is placed at the center of a square ABCD of side 10 cm . Find the work done ("in" mu J) in moving a charge of 1 mu C from A to B.

An infinitely long thin wire carrying a uniform linear static charge density lambda is placed along the z-axis Fig. The wire is set into motion along its length with a uniform velocity vecv=vhatk . Calculate the poynting vector vecS=1/(mu_0)(vecExxvecB) .

An infinitely long thin wire carrying a uniform linear static charge density lambda is placed along the z-axis Fig. The wire is set into motion along its length with a uniform velocity vecv=vhatk . Calculate the poynting vector vecS=1/(mu_0)(vecExxvecB) .