Electric and magnetic dipole strength in 112,114,116,118,120,124Sn

S. Bassauer (1); P. von Neumann-Cosel (1); P.-G. Reinhard (2); A.; Tamii (3); S. Adachi (3); C.A. Bertulani (4); P.Y. Chan (3); A. D'Alessio; (1); H. Fujioka (5); H. Fujita (3); Y. Fujita (3); G. Gey (3); M. Hilcker; (1); T.H. Hoang (3); A. Inoue (3); J. Isaak (1); C. Iwamoto (6); T. Klaus; (1); N. Kobayashi (3); Y. Maeda (7); M. Matsuda (8); N. Nakatsuka (1); S.; Noji (9); H.J. Ong (10,3); I. Ou (11); N. Pietralla (1); V.Yu. Ponomarev (1),; M.S. Reen (12); A. Richter (1); M. Singer (1); G. Steinhilber (1); T. Sudo; (3); Y. Togano (13); M. Tsumura (14); Y. Watanabe (15); V. Werner (1) ((1); Institut f\"ur Kernphysik; Technische Universit\"at Darmstadt; D-64289; Darmstadt; Germany; (2) Institut f\"ur Theoretische Physik II; Universit\"at; Erlangen; D-91058 Erlangen; Germany; (3) Research Center for Nuclear Physics,; Osaka University; Ibaraki; Osaka 567-0047; Japan; (4) Department of Physics; and Astronomy; Texas A\&M University-Commerce; Commerce; Texas 75429; USA,; (5) Department of Physics; Tokyo Institute of Technology; Tokyo 152-8551,; Japan; (6) RIKEN; Nishina Center for Accelerator-Based Science; 2-1 Hirosawa,; 351-0198 Wako; Saitama; Japan; (7) Department of Applied Physics; Miyazaki; University; Miyazaki 889-2192; Japan; (8) Department of Communications; Engineering; Graduate School of Engineering; Tohoku University; Aramaki Aza; Aoba; Aoba-ku; Sendai 980-8579; Japan; (9) National Superconducting Cyclotron; Laboratory; Michigan State University; East Lansing; Michigan 48824; USA,; (10) Institute of Modern Physics; Chinese Academy of Sciences; Lanzhou,; 730000; China; (11) Okayama University; Okayama 700-8530; Japan; (12); Department of Physics; Akal University; Talwandi Sabo; Bathinda Punjab-151; 302; India; (13) Department of Physics; Rikkyo University; Tokyo; Japan; (14); Department of Physics; Kyoto University; Kyoto 606-8502; Japan (15); Department of Physics; University of Tokyo; Tokyo 113-8654; Japan)

arXiv:2007.06010·nucl-ex·September 30, 2020

Electric and magnetic dipole strength in 112,114,116,118,120,124Sn

S. Bassauer (1), P. von Neumann-Cosel (1), P.-G. Reinhard (2), A., Tamii (3), S. Adachi (3), C.A. Bertulani (4), P.Y. Chan (3), A. D'Alessio, (1), H. Fujioka (5), H. Fujita (3), Y. Fujita (3), G. Gey (3), M. Hilcker, (1), T.H. Hoang (3), A. Inoue (3), J. Isaak (1)

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TL;DR

This study investigates electric and magnetic dipole excitations in various tin isotopes using inelastic proton scattering, revealing detailed properties of the giant dipole resonance and differences from previous gamma-ray experiments.

Contribution

It provides new measurements of E1 and M1 strength distributions in tin isotopes, including electric dipole polarizability and resonance widths, using advanced experimental and analysis techniques.

Findings

01

IVGDR widths are approximately constant at about 4.5 MeV across isotopes.

02

E1 strengths below neutron threshold agree with gamma-gamma experiments.

03

Significant differences in photoabsorption cross sections compared to previous gamma experiments.

Abstract

Inelastic proton scattering experiments were performed at the Research Center for Nuclear Physics, Osaka, with a 295 MeV beam covering laboratory angles 0{\deg}-6{\deg} and excitation energies 6-22 MeV. Cross sections due to E1 and M1 excitations were extracted with a multipole decomposition analysis and then converted to reduced transition probabilities with the "virtual photon method" for E1 and the "unit cross section method" for M1 excitations, respectively. Including a theory-aided correction for the high excitation energy region not covered experimentally, the electric dipole polarizability was determined from the E1 strength distributions. Total photoabsorption cross sections derived from the E1 and M1 strength distributions show significant differences compared to those from previous ( $γ$ ,xn) experiments in the energy region of the isocvector giant dipole resonance (IVGDR).…

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