Quenching of single-particle strength inferred from nucleon-removal transfer reactions on $^{15}$C

Y. C. Jiang (1; 2); J. Chen (1; 3); B. P. Kay (3); C. R. Hoffman (3); T. L. Tang (3); I. A. Tolstukhin (3); M. R. Xie (4; 5); J. G. Li (4; 5); N. Michel (4; 5); M. L. Avila (3); Y. Ayyad (6); D. Bazin (7); S. Bennett (8); J. A. Clark (3); S. J. Freeman (8; 9); H. Jayatissa (3); G. Li (10); W. P. Liu (1; 2); J. L. Lou (10); A. Munoz-Ramos (6); C. M\"uller-Gatermann (3); T. Nathan (7); D. Santiago-Gonzalez (3); D. K. Sharp (8); Y. P. Shen (2); A. H. Wuosmaa (11); C. X. Yuan (12) ((1) Department of Physics; Southern University of Science; Technology; Shenzhen; Guangdong; China; (2) China Institute of Atomic Energy; Beijing; China; (3) Physics Division; Argonne National Laboratory; Lemont; Illinois; USA; (4) Institute of Modern Physics; Chinese Academy of Sciences; Lanzhou; Gansu; China; (5) School of Nuclear Science; Technology; University of Chinese Academy of Sciences; Beijing; China; (6) IGFAE; Universidade de Santiago de Compostela; Santiago de Compostela; Spain; (7) Facility for Rare Isotope Beams; Michigan State University; East Lansing; Michigan; USA; (8) Department of Physics; University of Manchester; Manchester; United Kingdom; (9) EP Department; CERN; Geneva; Switzerland; (10) School of Physics; State Key Laboratory of Nuclear Physics; Technology; Peking University; Beijing; China; (11) Department of Physics; University of Connecticut; Storrs; Connecticut; USA; (12) Sino-French Institute of Nuclear Engineering; Technology; Sun Yat-Sen University; Zhuhai; Guangdong; China)

arXiv:2506.03685·nucl-ex·August 7, 2025

Quenching of single-particle strength inferred from nucleon-removal transfer reactions on $^{15}$C

Y. C. Jiang (1, 2), J. Chen (1, 3), B. P. Kay (3), C. R. Hoffman (3), T. L. Tang (3), I. A. Tolstukhin (3), M. R. Xie (4, 5), J. G. Li (4, 5), N. Michel (4, 5), M. L. Avila (3), Y. Ayyad (6), D. Bazin (7), S. Bennett (8), J. A. Clark (3), S. J. Freeman (8, 9), H. Jayatissa (3)

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TL;DR

This study investigates the quenching of single-particle strength in $^{15}$C through neutron removal transfer reactions, comparing results with knockout reactions to understand the influence of reaction type and neutron-proton asymmetry.

Contribution

It provides the first systematic comparison of neutron removal transfer reactions with knockout reactions on $^{15}$C at extreme neutron-proton asymmetry, revealing consistent quenching factors.

Findings

01

Neutron removal transfer reactions yield quenching factors consistent with neutron-adding reactions.

02

Quenching factors show limited dependence on neutron-proton asymmetry at extreme conditions.

03

Results suggest correlations are similar across different reaction probes at high asymmetry.

Abstract

The difference in the proton and neutron separation energies ( $Δ S$ ) of the weakly bound $^{15}$ C ground state is -19.86 MeV, an extreme value. Data from intermediate-energy heavy-ion induced (HI-induced) knockout reactions on nuclei spanning $- 20 ≲ Δ S ≲ + 20$ MeV, suggest that the degree to which single-particle strength is quenched, $R_{s}$ , has a negative correlation with $Δ S$ , decreasing from unity around $- 20$ ~MeV to around 0.2 at $+ 20$ ~MeV. For the $^{15}$ C ground state ( $R_{s} = 0.96 (4)$ in HI-induced knockout), contrasting results have recently been obtained via the neutron-adding transfer reaction, which reveal a value of $R_{s} = 0.64 (15)$ , similar to the value observed at modest $Δ S$ and more extreme values of $Δ S$ with reaction probes other than HI knockout. In order to explore the any potential differences between $a dd in g$ and…

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