What are the units of `K (1)/(4pi in_(0))` ?

What are the unit of (mu_(0))/(4pi)

What are the dimensions of mu_0//4pi ?

A point charge 'Q' is placed at the centre of a spherical cavity of radius 'b' carved inside a solid conducting sphere of radius 'a'. Then total energy of the system is: [k = (1)/(4pi in_(0))]

The correct formula for potential energy in the electric field of an electrical dipole body is, when the angle of the electric dipole is theta with the electric field (k=(1)/( 4pi in_(0)))

The total flux associated with given cube will be - where 'a' is side of cube :- ( (1)/(in_(0)) = 4pi xx 9 xx 10^(9) )

A sphere of radius R contains charge density rho(r )=A (R-r ) , for 0 lt r lt R . The total electric charge inside the sphere is Q. The electric outside the sphere is (k=1/(4pi in_(0)))

An infinite number of charges each equal to q are placed along the x-axis at x= 1m,x=2m,x=4m,x=8m , ... and so on. Find the potential and electric field at the point x = 0 due to this set of charges. What will be potential and electric field ifin the above set up if the consecutive charge have opposite sign? [(q)/(2pi in_(0)),(q)/(3pi in_(0)), (q)/(6pi in_(0)),(q)/(5pi in_(0))]

The dimensions of (1)/(2) in_(0) E^(2) , where in_0 is permittivity of free space and E is electric field, is :-

In the figure shown, conducting shells A and B have charges Q and 2Q distributed uniformly over and B. Value of V_(A) - V_(B) k is (kQ)/(nR) . Find n ( k = (1)/(4 pi in_(0))