Answer:
Angular velocity is same as frequency of oscillation in this case.
ω = [tex]\sqrt{\frac{7K}{m} }[/tex] x [tex][\frac{L^{2}}{mK}]^{3/14}[/tex]
Explanation:
- write the equation F(r) = -K[tex]r^{4}[/tex] with angular momentum L
- Get the necessary centripetal acceleration with radius r₀ and make r₀ the subject.
- Write the energy of the orbit in relative to r = 0, and solve for "E".
- Find the second derivative of effective potential to calculate the frequency of small radial oscillations. This is the effective spring constant.
- Solve for effective potential
- ω = [tex]\sqrt{\frac{7K}{m} }[/tex] x [tex][\frac{L^{2}}{mK}]^{3/14}[/tex]
