Abstract
The roles of simultaneous (one-step) and sequential (two-step) transfer processes in the reaction $^{208}\mathrm{Pb}$($p$,$t$)$^{206}\mathrm{Pb}$(${3}^{+}$,1.34 MeV) are investigated. Both processes are accurately evaluated employing realistic wave functions and finite-range interactions. The sequential transfer process is found to be dominant in this reaction, contrary to the conclusion of Nagarajan et al. The comparison of the polarization asymmetry calculation with the data confirms this result.NUCLEAR REACTIONS $^{208}\mathrm{Pb}$($p$,$t$) ${3}^{+}$, ${E}_{p}=22,35$ MeV; first and second order DWBA analysis, calculated $\ensuremath{\sigma}(\ensuremath{\theta})$, $A(\ensuremath{\theta})$. Reaction mechanism.
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