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

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

Consider an infinite line charge having uniform linear charge density and passing through the axis of a cylinder is removed.

The dimensional formula of linear charge density lambda is

The electric field at distance .r. from infinte line of charge ("having linear charge density" lambda) is

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

If linear charge density of a wire as shown in the figure 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

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) .

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 .