Answer:
The potential that is as a result of the dipole at <x,0,0> is [tex]V_x = [\frac{4kqs}{4x^2 -s^2} ][/tex]
The potential that is as a result the dipole at <0,y,0> is [tex]V_y = 0 volt[/tex]
Explanation:
From the question we are told that
The dipole moment is [tex]p= qs[/tex]
The potential at the position <x,0,0 > on the x-axis is mathematically represented as
[tex]V_{x} = V_+ + V_-[/tex]
So this can be evaluated as
[tex]V_{x} = [\frac{kq}{x- \frac{s}{2} } ] + [\frac{kq}{x+ \frac{s}{2} } ][/tex]
where s is the distance between the charges
=> [tex]V_{x} =kq [[\frac{1}{x - \frac{s}{2} } ] - [\frac{1}{x+ \frac{s}{2} } ]][/tex]
[tex]V_x = [\frac{4kqs}{4x^2 -s^2} ][/tex]
The potential at the position <0,y,0 > on the y-axis is mathematically represented as
[tex]V_y = V_+ V_-[/tex]
So this can be evaluated as
[tex]V_y = [\frac{kq}{\sqrt{y^2 + (\frac{s}{2} )^2} } ] - [\frac{kq}{\sqrt{y^2 + (\frac{s}{2} )^2} } ][/tex]
The negative sign shows that the potential value right side of the minus sign is a negative potential
[tex]V_y = 0 volt[/tex]
Note [tex]k = \frac{1}{4 \pi \epsilon _o }[/tex]
