Universe (Mar 2021)

Initial State Interaction for the <sup>20</sup>Ne + <sup>130</sup>Te and <sup>18</sup>O + <sup>116</sup>Sn Systems at 15.3 AMeV from Elastic and Inelastic Scattering Measurements

  • Diana Carbone,
  • Roberto Linares,
  • Paulina Amador-Valenzuela,
  • Salvatore Calabrese,
  • Francesco Cappuzzello,
  • Manuela Cavallaro,
  • Suna Firat,
  • Maria Fisichella,
  • Alessandro Spatafora,
  • Luis Acosta,
  • Clementina Agodi,
  • Ismail Boztosun,
  • Giuseppe A. Brischetto,
  • Daniela Calvo,
  • Efrain R. Chávez Lomelí,
  • Irene Ciraldo,
  • Mauro Cutuli,
  • Franck Delaunay,
  • Nikit Deshmukh,
  • Paolo Finocchiaro,
  • Antonino Foti,
  • Aylin Hacisalihoglu,
  • Felice Iazzi,
  • Laura La Fauci,
  • Gaetano Lanzalone,
  • Nilberto H. Medina,
  • Djalma Mendes,
  • José R. B. Oliveira,
  • Athina Pakou,
  • Luciano Pandola,
  • Horia Petrascu,
  • Federico Pinna,
  • Giuseppe Russo,
  • Onoufrios Sgouros,
  • Selçuk O. Solakci,
  • Vasilis Soukeras,
  • George Souliotis,
  • Domenico Torresi,
  • Salvatore Tudisco,
  • Aydin Yildirim,
  • Vinicius A. B. Zagatto

DOI
https://doi.org/10.3390/universe7030058
Journal volume & issue
Vol. 7, no. 3
p. 58

Abstract

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Double charge exchange (DCE) reactions could provide experimentally driven information about nuclear matrix elements of interest in the context of neutrinoless double-β decay. To achieve this goal, a detailed description of the reaction mechanism is mandatory. This requires the full characterization of the initial and final-state interactions, which are poorly known for many of the projectile-target systems involved in future DCE studies. Among these, we intend to study the 20Ne + 130Te and 18O + 116Sn systems at 15.3 AMeV, which are particularly relevant due to their connection with the 130Te→130Xe and 116Cd→116Sn double-β decays. We measure the elastic and inelastic scattering cross-section angular distributions and compare them with theoretical calculations performed in the optical model, one-step distorted wave Born approximation, and coupled-channel approaches using the São Paulo double-folding optical potential. A good description of the experimental data in the whole explored range of transferred momenta is obtained provided that couplings with the 21+ states of the projectile and target are explicitly included within the coupled-channel approach. These results are relevant also in the analysis of other quasi-elastic reaction channels in these systems, in which the same couplings should be included.

Keywords