Answer :
The axial field is the integration of the field from each element of charge around the ring. Because of symmetry, the field is only in the direction of the axis. The field from an element ds in the ring is
dE = (qs*ds)cos(T)/(4*pi*e0)*(x^2 + R^2)
where x is the distance along the axis from the plane of the ring, R is the radius of the ring, qs is the linear charge density, T is the angle of the field from the x-axis.
However, cos(T) = x/sqrt(x^2 + R^2)
so the equation becomes
dE = (qs*ds)*[x/sqrt(x^2 + R^2)]/(4*pi*e0)*(x^2 + R^2)
dE =[qs*ds/(4*pi*e0)]*x/(x^2 + R^2)^1.5
Integrating around the ring you get
E = (2*pi*R/4*pi*e0)*x/(x^2 + R^2)^1.5
E = (R/2*e0)*x*(x^2 + R^2)^-1.5
we differentiate wrt x, the term R/2*e0 is a constant K, and the derivative is
dE/dx = K*{(x^2 + R^2)^-1.5 +x*[(-1.5)*(x^2 + R^2)^-2.5]*2x}
dE/dx = K*{(x^2 + R^2)^-1.5 - 3*x^2*(x^2 + R^2)^-2.5}
to find the maxima set this = 0, giving
(x^2 + R^2)^-1.5 - 3*x^2*(x^2 + R^2)^-2.5 = 0
mult both side by (x^2 + R^2)^2.5 to get
(x^2 + R^2) - 3*x^2 = 0
-2*x^2 + R^2 = 0
-2*x^2 = -R^2
x = (+/-)R/sqrt(2)
dE = (qs*ds)cos(T)/(4*pi*e0)*(x^2 + R^2)
where x is the distance along the axis from the plane of the ring, R is the radius of the ring, qs is the linear charge density, T is the angle of the field from the x-axis.
However, cos(T) = x/sqrt(x^2 + R^2)
so the equation becomes
dE = (qs*ds)*[x/sqrt(x^2 + R^2)]/(4*pi*e0)*(x^2 + R^2)
dE =[qs*ds/(4*pi*e0)]*x/(x^2 + R^2)^1.5
Integrating around the ring you get
E = (2*pi*R/4*pi*e0)*x/(x^2 + R^2)^1.5
E = (R/2*e0)*x*(x^2 + R^2)^-1.5
we differentiate wrt x, the term R/2*e0 is a constant K, and the derivative is
dE/dx = K*{(x^2 + R^2)^-1.5 +x*[(-1.5)*(x^2 + R^2)^-2.5]*2x}
dE/dx = K*{(x^2 + R^2)^-1.5 - 3*x^2*(x^2 + R^2)^-2.5}
to find the maxima set this = 0, giving
(x^2 + R^2)^-1.5 - 3*x^2*(x^2 + R^2)^-2.5 = 0
mult both side by (x^2 + R^2)^2.5 to get
(x^2 + R^2) - 3*x^2 = 0
-2*x^2 + R^2 = 0
-2*x^2 = -R^2
x = (+/-)R/sqrt(2)