We can start considering the surface charge density which is
[tex]\sigma = \frac{Q}{\pi R^2}[/tex]
Here,
Q = Total charge and R is the radius of the Disk.
A ring of thickness 'da' centered on the disk as shown has differential area given by
[tex]dA =(2\pi a)da[/tex]
And thus a charge given by
[tex]dq = \sigma dA = (2\pi a\sigma) da[/tex]
The field produced by this ring of charge is along the x-axis and is given as
[tex]dE_x = \frac{kx2\pi a \sigma da}{(x^2+a^2)^{3/2}} \rightarrow \text{Electric field on the axis of a ring of charge}[/tex]
The total field is given by simply integrating over a from 0 to r, then
[tex]E_x = \int^r_0 \frac{(kx2\pi a \sigma )da}{(x^2+a^2)^{3/2}}[/tex]
[tex]E_x = kx\pi \sigma \int_0^r \frac{(2a)da}{(x^2+a^2)^{3/2}}[/tex]
[tex]E_x = kx\pi \sigma \bigg [ -\frac{1}{2(x^2+a^2)^{1/2}} \bigg]^r_0[/tex]
Replacing we have finally,
[tex]E_x = 2\pi k\sigma (1-\frac{x}{(x^2+r^2)^{1/2}})[/tex]
Now that is the electric field of a uniformly charged disk:
[tex]E = 2\pi k\sigma (1-\frac{x}{\sqrt{x^2+r^2}})[/tex]
Here,
k = Coulomb's constant
[tex]\sigma[/tex] = Surface charge density
x = Distance from center
r = Radius of the Disk
Although the distances are not mentioned in the statement we can establish distances to the center of the disk of approximately 5 cm (In such case the expression could simply be left in terms of x)
Replacing then we would have to,
[tex]E = 2\pi (9*10^9)(7.9*10^{-3})(1-\frac{x}{\sqrt{(x)^2+(35*10^{-2})^2}}})[/tex]
Assuming the value of x, we will have,
[tex]E = 2\pi (9*10^9)(7.9*10^{-3})(1-\frac{5*10^{-2}}{\sqrt{(5*10^{-2})^2+(35*10^{-2})^2}}})[/tex]
[tex]E = 383.556*10^6N/C[/tex]
