Effective field theory analysis of the Coulomb breakup of the one-neutron halo nucleus $$^{19}$$C
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Published:2023-11-20
Issue:11
Volume:59
Page:
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ISSN:1434-601X
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Container-title:The European Physical Journal A
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language:en
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Short-container-title:Eur. Phys. J. A
Author:
Capel PierreORCID, Phillips Daniel R.ORCID, Andis Andrew, Bagnarol Mirko, Behzadmoghaddam Behnaz, Bonaiti Francesca, Bubna RishabhORCID, Capitani Ylenia, Duerinck Pierre-Yves, Durant VictoriaORCID, Döpper Niklas, El Boustani Aya, Farrell Roland, Geiger Maurus, Gennari Michael, Goldberg Nitzan, Herko JakubORCID, Kirchner Tanja, Kubushishi Live-Palm, Li Zhen, Muli Simone S. Li, Long Alexander, Martin Brady, Mohseni Kamyar, Moumene Imane, Paracone Nicola, Parnes Elad, Romeo Beatriz, Springer Victor, Svensson Isak, Thim Oliver, Yapa Nuwan
Abstract
AbstractWe analyse the Coulomb breakup of $$^{19}$$
19
C measured at 67A MeV at RIKEN. We use the Coulomb-Corrected Eikonal (CCE) approximation to model the reaction and describe the one-neutron halo nucleus $$^{19}$$
19
C within Halo Effective Field Theory (Halo EFT). At leading order we obtain a fair reproduction of the measured cross section as a function of energy and angle. The description is insensitive to the choice of optical potential, as long as it accurately represents the size of $${}^{18}$$
18
C. It is also insensitive to the interior of the $${}^{19}$$
19
C wave function. Comparison between theory and experiment thus enables us to infer asymptotic properties of the ground state of $$^{19}$$
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C: these data put constraints on the one-neutron separation energy of this nucleus and, for a given binding energy, can be used to extract an asymptotic normalisation coefficient (ANC). These results are confirmed by CCE calculations employing next-to-leading order Halo EFT descriptions of $${}^{19}$$
19
C: at this order the results for the Coulomb breakup cross section are completely insensitive to the choice of the regulator. Accordingly, this reaction can be used to constrain the one-neutron separation energy and ANC of $${}^{19}$$
19
C.
Funder
U.S. Department of Energy Deutsche Forschungsgemeinschaft Johannes Gutenberg-Universität Mainz
Publisher
Springer Science and Business Media LLC
Subject
Nuclear and High Energy Physics
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