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Mazumdar, I.; Arora, Varun; Bhasin, V. S.

doi:10.1103/physrevc.61.051303

Cited by 40 publications

(51 citation statements)

References 10 publications

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“…The result for 11 Li, r 2 nn exp = (6.6 ± 1.5) fm, is in close agreement with both the LO, r 2 nn = (6.8 ± 1.8) fm, and NLO, r 2 nn = (6.3 ± 0.5) fm, calculations found using the two-body virtual energy reported in [48], E nc = −800 keV. However, due to the large uncertainties in both the theoretical and experimental values for 11 Li, there exists a large range of E nc values which would produce a r 2 nn value in agreement with the experimental value of Marqués et al [50]. The LO result for 14 Be, r 2 nn = (4.1 ± 0.5) fm, is about a Fermi below the the experimental value from Ref.…”

Section: B Range Corrections To 2n Halo Nuclei Mean Square Radiimentioning

confidence: 99%

“…For the Borromean halo nuclei 11 Li and 14 Be, in which all two-body subsystems are unbound, the general tendency is for a positive effective range to shift all mean square radii to smaller values. The only exception is the case of 11 Li using the central value of the n-c energy E nc = (−25 ± 15) keV [39].…”

Section: B Range Corrections To 2n Halo Nuclei Mean Square Radiimentioning

confidence: 99%

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Range corrections for two-neutron halo nuclei in effective theory

Canham¹,

Hammer²

2010

Nuclear Physics A

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The range corrections to the universal properties and structure of two-neutron halo nuclei are investigated within an effective quantum mechanics framework. Treating the nucleus as an effective three-body system, we make a systematic improvement upon previous calculations by calculating the linear range corrections at next-to-leading order. Since the effective ranges for the neutroncore interactions are not known, we estimate the effective range to be set by the inverse of the pion mass. We investigate the possibility of excited Efimov states in two-neutron halo nuclei and calculate their mean square radii to next-to-leading order. We find that the effective range corrections are generally small and the leading order predictions are very robust. * Electronic address: canham@hiskp.uni-bonn.de † Electronic address: hammer@hiskp.uni-bonn.de

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Section: B Range Corrections To 2n Halo Nuclei Mean Square Radiimentioning

confidence: 99%

Section: B Range Corrections To 2n Halo Nuclei Mean Square Radiimentioning

confidence: 99%

Range corrections for two-neutron halo nuclei in effective theory

Canham¹,

Hammer²

2010

Nuclear Physics A

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“…From the earliest studies of halo nuclei, 20 C has been suggested as a good candidate for Efimov states [18], with future theoretical work supporting this prediction [19,20]. We critically examine these earlier studies and perform an improved analysis in the framework of an effective theory.…”

Section: Introductionmentioning

confidence: 99%

“…III C, there possibly exists one Efimov excited state in 20 C for E nc < 165 keV. The mean square radii for this excited state were calculated over a range of E nc values and plotted, with leading order error bands, in Fig.…”

Section: B Mean Square Radii and Geometry Of 2n Halo Nucleimentioning

confidence: 99%

Universal properties and structure of halo nuclei

2008

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The universal properties and structure of halo nuclei composed of two neutrons (2n) and a core are investigated within an effective quantum mechanics framework. We construct an effective interaction potential that exploits the separation of scales in halo nuclei and treat the nucleus as an effective three-body system. The uncertainty from higher orders in the expansion is quantified through theoretical error bands. First, we investigate the possibility to observe excited Efimov states in 2n halo nuclei. Based on the experimental data, 20 C is the only halo nucleus candidate to possibly have an Efimov excited state, with an energy less than 7 keV below the scattering threshold. Second, we study the structure of 20 C and other 2n halo nuclei. In particular, we calculate their matter form factors, radii, and two-neutron opening angles. * Electronic address: canham@itkp.uni-bonn.de † Electronic address: hammer@itkp.uni-bonn.de

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“…The properties of halo nuclei can be understood by treating the nucleus as an effective three body system consisting of a Core and two neutrons (Core-n-n) [4,[8][9][10] with the assumption that excitation energies of the core, E * core , are much larger than the other energy scales, E nn and E nc . It is found that the relative properties of the Efimov states can be expressed in terms of ratios (see for example Ref.…”

Section: Introductionmentioning

confidence: 99%

How to Study Efimov States in Exotic Nuclei?

Macchiavelli

2015

Few-Body Syst

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The existence of Efimov states in atomic nuclei has been predicted by several authors considering 3-body systems of the form Core-neutron-neutron. While these states appear elusive and very challenging experimentally, we discuss possible reactions that can be used to produce and study them in exotic (weaklybound) nuclei. Following simple arguments, we show that cross-sections relative to the ground states should scale with the parameter λ 0 , which is the same scale factor for binding energies and radii. We derive back of the envelope estimates for: one-and two-neutron transfer reactions, and inelastic scattering. The (d, p) reaction appears as the most promising approach and we discuss in more detail some experimental considerations using the example of 19 C(d, p) 20 C. These initial estimates could serve as a starting point for more refined and realistic calculations, which will be required for careful experimental planning and further analysis.

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Three-body analysis of the occurrence of Efimov states in2nhalo nuclei such as19B,

Cited by 40 publications

References 10 publications

Range corrections for two-neutron halo nuclei in effective theory

Range corrections for two-neutron halo nuclei in effective theory

Universal properties and structure of halo nuclei

How to Study Efimov States in Exotic Nuclei?

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