A point charge `Q_(1)=-125mu C` is fixed at the center of an insulated disc of mass 1 kg. The disc rests on a rough horizontal plane. Another charge `Q_(2)=125mu C` is fixed verically above the center of the disc at a height h=1m. After the disc is displaced slightly in the horizontall direction (friction is sufficient to prevent slipping), find the period of oscillation of disc.

Let the radius of the disc be R. If the disc is displaced x, The corresponding angular dispalcement `theta=x//R`.
The restoring torque `tau` about the point of contact of disc with ground.
`tau_(p)=(F sin theta)R`
`(F sin theta)R=1alpha=[(MR)^(2)/(2)+MR^(2)]alpha`
where `F=(Q^(2)x)/(4 pi epsilon_(0)(h^(2)+x^(2)))`
and `sin theta=(R )/(sqrt((h^(2)+x^(2)))`
Hence `(Q^(2)xR)/(4 pi epsilon_(0)(h^(2)+x^(2))^(3//2))=[(MR^(2))/(2)+MR^(2)]alpha`
or `alpha=(Q^(2)x)/(6 pi epsilon_(0)MR(h^(2)+x^(2))^(3//2))`
for `x ltlt h, alpha~=-(Q^(2)x)/(6 pi epsilon_(0)MRh^(3))`
`alpha=(a)/(R ) ~=-(Q^(2)x)/(6 pi epsilon_(0)MRh^(3))`
Negative sign is being introduced because angular acceleration and angular displacement are opposite to each other. Thus, ltbr. `a=(Q^(2)x)/(6 pi epsilon_(0)MRh^(3))`
Hence, `omega=sqrt((Q^(2))/(6 pi epsilon_(0)MRh^(3)))`
`T=2 pi sqrt((6 pi epsilon_(0)MRh^(3))/(Q^2)) =2pi (h/Q)sqrt((6 pi epsilon_(0)Mh))`.