Energy spectrum of neutron-rich helium isotopes: Complex made simple

Fossez, K.; Rotureau, J.; Nazarewicz, W.

doi:10.1103/physrevc.98.061302

Cited by 28 publications

(21 citation statements)

References 80 publications

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“…Common to all these approaches is that a configuration space interaction that is given in terms of SHO matrix elements is expanded on a basis containing SHO and Berggren states, hence it is still an open question how a direct implementation of the interactions in a basis with continuum degrees of freedom might modify existing results. It is worth noting that such a construction has been achieved for phenomenological GSM interactions that have been tuned for light nuclei [217][218][219][220][221][222]. In light nuclei, the NCSMC has been applied with impressive success to describe a variety of exotic nuclei with up to three-cluster structures.…”

Section: Toward the Drip Linesmentioning

confidence: 99%

“…sections 2.3.8 and 3.2.4), as well as the GSM Coupled Channel (GSM-CC) approach, which was developed to describe reactions between light projectiles and targets that are treated in the GSM with a core [221,328,329]. Thus far, applications of the GSM-CC have been based on phenomenological valence-space interactions, but new efforts are underway to directly construct suitable Hamiltonians based on EFT principles [220,330], or derive the effective interactions from chiral forces with the techniques discussed in section 2.3 (see [214,215]). Of course, the GSM-CC ideas could also be applied to the No-Core GSM [153,155,218], although the computational complexity would limit such an approach to light nuclei.…”

Section: Interfacing With Reaction Theorymentioning

confidence: 99%

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A Guided Tour of ab initio Nuclear Many-Body Theory

2020

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Over the last decade, new developments in Similarity Renormalization Group techniques and nuclear many-body methods have dramatically increased the capabilities of ab initio nuclear structure and reaction theory. Ground and excited-state properties can be computed up to the tin region, and from the proton to the presumptive neutron drip lines, providing unprecedented opportunities to confront two-plus three-nucleon interactions from chiral Effective Field Theory with experimental data. In this contribution, I will give a broad survey of the current status of nuclear many-body approaches, and I will use selected results to discuss both achievements and open issues that need to be addressed in the coming decade.

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Section: Toward the Drip Linesmentioning

confidence: 99%

Section: Interfacing With Reaction Theorymentioning

confidence: 99%

A Guided Tour of ab initio Nuclear Many-Body Theory

2020

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“…We want to mention here that a similar approach was employed in Ref. [29] to construct an effective neutronneutron interaction for the description of the helium isotopic chain in the Berggren basis. In that case, using only the central term V 01 c , a good reproduction of weaklybound and unbound states in helium nuclei was achieved.…”

Section: B Gamow Shell Model Hamiltonianmentioning

confidence: 99%

“…By means of the principal-component analysis, it was concluded that a very reasonable description of energies of 6 ≤ A ≤ 9 nuclei (rms deviation from experiment of 250 keV) could be achieved with only four interaction parameters. In the follow-up paper [29], carried out in the spd space, experimental energies and widths of 5−8 He could be reproduced within tens of keV precision by adjusting only one parameter (the strength of spinsinglet central neutron-neutron term). In this work, we construct the minimal GSM model to describe binding energies and spectra of 5 ≤ A ≤ 11 nuclei in the sp space by carrying out simultaneous optimization of the corenucleon potential and the valence two-body interaction with the mass-dependent interaction scaling to effectively account for the missing three-body forces.…”

mentioning

confidence: 99%

Gamow Shell Model description of Li isotopes and their mirror partners

Mao,

Rotureau,

Nazarewicz

et al. 2020

Preprint

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Background: Weakly bound and unbound nuclei close to particle drip lines are laboratories of new nuclear structure physics at the extremes of neutron/proton excess. The comprehensive description of these systems requires an open quantum system framework that is capable of treating resonant and nonresonant many-body states on equal footing.Purpose: In this work, we construct the minimal complex-energy configuration interaction approach to describe binding energies and spectra of selected 5 ≤ A ≤ 11 nuclei.Method: We employ the complex-energy Gamow shell model (GSM) assuming a rigid 4 He core. The effective Hamiltonian, consisting of a core-nucleon Woods-Saxon potential and a simplified version of the Furutani-Horiuchi-Tamagaki interaction with the mass-dependent scaling, is optimized in the sp space. To diagonalize the Hamiltonian matrix, we employ the Davidson method and the Density Matrix Renormalization Group technique.Results: Our optimized GSM Hamiltonian offers a good reproduction of binding energies and spectra with the root-mean-square (rms) deviation from experiment of 160 keV. Since the model performs well when used to predict known excitations that have not been included in the fit, it can serve as a reliable tool to describe poorly known states. A case in point is our prediction for the pair of unbound mirror nuclei 10 Li-10 N in which a huge Thomas-Ehrman shift dramatically alters the pattern of low-energy excitations. Conclusion:The new model will enable comprehensive studies of structure and reactions aspects of light drip-line nuclei.

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“…These drawbacks include the scaling behavior as a function of mass number, the convergence of observables as a function of basis states, the validity of many-body truncations, and constraints regarding which nuclear interactions can be used. A special but related challenge is the development, within the basic model, of approaches accounting for the coupling to the continuum-these are mandatory to describe, for instance, weakly bound nuclear systems [18,19].…”

Section: Introductionmentioning

confidence: 99%

Local two- and three-nucleon chiral interactions

Piarulli,

Schiavilla

2021

Preprint

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Understanding the structure and reactions of nuclei from first principles has been a long-standing goal of nuclear physics. In this respect, fewand many-body systems provide a unique laboratory for studying nuclear interactions. In the past couple of decades, the modeling of nuclear interactions has progressed significantly owing, in particular, to the development of chiral effective field theory (χEFT), a low-energy effective representation of quantum chromodynamics (QCD). Within χEFT, many studies have dealt with the construction of both two-and three-nucleon interactions. The aim of the present article is to provide a concise account of chiral interaction models that are local in configuration space, and to report on a selection of recent results for nuclear systems obtained with these interactions.

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Energy spectrum of neutron-rich helium isotopes: Complex made simple

Cited by 28 publications

References 80 publications

A Guided Tour of ab initio Nuclear Many-Body Theory

A Guided Tour of ab initio Nuclear Many-Body Theory

Gamow Shell Model description of Li isotopes and their mirror partners

Local two- and three-nucleon chiral interactions

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