Probing the fission of $^{220}$Ra${^\star}$ at E$^{\star}$ $\approx$ 31.8--45.4 MeV

In this work, fission of moderately excited compound nucleus $^{220}$Ra${^\star}$ produced in $^{12}$C+$^{208}$Pb reaction at E$_{\rm lab}$ = 81.9, 75.8, and 67.5 MeV has been studied. 28 fission fragments, within the mass range 60$\leq$A$\leq$141, have been identified based on their characteristic decay $\gamma$-lines and half-lives. The yields of different fission fragments have been analyzed to generate isotopic and isobaric yield distributions. The value of the mass dispersion parameter, $\sigma^2_A$, is found to be 2.93 and 2.65 for Antimony (Sb) isotope at excitation energy E$^{\star}$ = 45.4 and 39.6 MeV, and 1.24 for Indium (In) isotope at E$^{\star}$ = 45.4 MeV. The charge dispersion parameter $\sigma_z$ for Sb is estimated to be 0.769 and 0.714 at E$^{\star}$ = 45.4 and 39.6 MeV, respectively. For In isotopes, the value of $\sigma_z$ is estimated to be 0.430 at E$^{\star}$ = 45.4 MeV. The value of mass and charge dispersion parameters for Sb and In isotopes display good agreement with the values reported in the literature for similar systems. It has been found that $^{99m}$Tc and $^{111}$In, medically important isotopes, populate in this system. The present investigations suggest that fission is a dominating mode of deexcitation of the compound nucleus, even at entrance channel energies slightly above the Coulomb barrier.