Your search keyword '"Goriely S."' showing total 1,483 results

51. Shell-model based study of the direct capture in neutron-rich nuclei

Author

Sieja, K. and Goriely, S.

Subjects

Nuclear Theory

Abstract

The radiative neutron capture rates for isotopes of astrophysical interest are commonly calculated within the statistical Hauser-Feshbach reaction model. Such an approach, assuming a high level density in the compound system, can be questioned in light and neutron-rich nuclei for which only a few or no resonant states are available. Therefore, in this work we focus on the direct neutron-capture process. We employ a shell-model approach in several model spaces with well-established effective interactions to calculate spectra and spectroscopic factors in a set of 50 neutron-rich target nuclei in different mass regions, including doubly-, semi-magic and deformed ones. Those theoretical energies and spectroscopic factors are used to evaluate direct neutron capture rates and to test global theoretical models using average spectroscopic factors and level densities based on the Hartree-Fock-Bogoliubov plus combinatorial method. The comparison of shell-model and global model results reveals several discrepancies that can be related to problems in level densities. All the results show however that the direct capture is non-negligible with respect to the by-default Hauser-Feshbach predictions and can be even 100 times more important for the most neutron-rich nuclei close to the neutron drip line., Comment: 10 pages, 9 figures, submitted to EPJ A

Published

2020

52. Low-mass low-metallicity AGB stars as an efficient i-process site explaining CEMP-rs stars

Author

Karinkuzhi, D., Van Eck, S., Goriely, S., Siess, L., Jorissen, A., Merle, T., Escorza, A., and Masseron, T.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Among Carbon-Enhanced Metal-Poor (CEMP) stars, some are found to be enriched in s-process elements (CEMP-s), in r-process elements (CEMP-r) or in both s- and r-process elements (CEMP-rs). The origin of the abundance differences between CEMP-s and CEMP-rs stars is presently unknown. It has been claimed that the i-process, whose site still remains to be identified, could better reproduce CEMP-rs abundances than the s-process. We analyze high-resolution spectra of 25 metal-poor stars, observed with the high-resolution HERMES spectrograph mounted on the Mercator telescope, La Palma, or with the UVES/VLT and HIRES/KECK spectrographs. We propose a new, robust classification method for CEMP-s and CEMP-rs stars using eight heavy element abundances. The abundance profiles of CEMP-s and CEMP-rs stars are derived and there appears to be an abundance continuum between the two stellar classes. CEMP-rs stars present most of the characteristics of extrinsic stars such as CEMP-s, CH, Barium and extrinsic S stars, with an even larger binarity rate among CEMP-rs stars than among CEMP-s stars. Stellar evolutionary tracks of an enhanced carbon composition (consistent with our abundance determinations) are necessary to explain the position of CEMP-s and CEMP-rs stars in the HR diagram using Gaia DR2 parallaxes; they are found to lie mostly on the RGB. CEMP-rs stars can be explained as being polluted by a low-mass, low-metallicity TP-AGB companion experiencing i-process nucleosynthesis after proton ingestion during its first convective thermal pulses. The global fitting of our i-process models to CEMP-rs stars is as good as the one of our s-process models to CEMP-s stars. As such, CEMP-rs stars could be renamed as CEMP-sr stars, since they represent a particular manifestation of the s-process at low-metallicities. For these objects a call for an exotic i-process site may not necessarily be required anymore., Comment: 35 pages, 26 figures, Accepted for publication in A&A, Final version

Published

2020

53. Discovery of technetium- and niobium-rich S stars: the case for bitrinsic stars

Author

Shetye, S., Van Eck, S., Goriely, S., Siess, L., Jorissen, A., Escorza, A., and Van Winckel, H.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

S stars are late-type giants with overabundances of s-process elements. They come in two flavours depending on the presence or not of technetium (Tc), an element without stable isotopes. Intrinsic S stars are Tc-rich and genuine asymptotic giant branch (AGB)stars while extrinsic S stars owe their s-process overabundances to the pollution from a former AGB companion, now a white dwarf(WD). In addition to Tc, another distinctive feature between intrinsic and extrinsic S stars is the overabundance of niobium (Nb) in the latter class. We discuss the case of the S stars BD+79 156 and o1Ori whose specificity is to share the distinctive features of both intrinsic and extrinsic S stars, namely the presence of Tc along with a Nb overabundance. BD+79 156 is the first clear case of a bitrinsic star, i.e. a doubly s-process-enriched object, first through mass transfer in a binary system, and then through internal nucleosynthesis (responsible for the Tc-enrichment in BD+79 156 which must therefore have reached the AGB phase of its evolution). This hybrid nature of the s-process pattern in BD+79 156 is supported by its binary nature and its location in the HR diagram just beyond the onset of the third dredge-up on the AGB. The Tc-rich, binary S-star o1Ori with a WD companion was another long-standing candidate for a similar hybrid s-process enrichment. However the marginal overabundance of Nb derived ino1Ori does not allow to trace unambiguously the evidence of a large pollution coming from the AGB progenitor of its current WD companion. As a side product, the current study offers a new way of detecting binary AGB stars with WD companions by identifying their Tc-rich nature along with a Nb overabundance., Comment: A & A Letters, accepted for publication

Published

2020

54. Astronuclear Physics: a Tale of the Atomic Nuclei in the Skies

Author

Arnould, M. and Goriely, S.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Nuclear Theory

Abstract

A century ago, nuclear physics entered astrophysics, giving birth to a new field of science referred to as "Nuclear Astrophysics". With time, it developed at an impressive pace into a vastly inter- and multidisciplinary discipline bringing into its wake not only astronomy and cosmology, but also many other sub-fields of physics, especially particle, solid-state and computational physics, as well as chemistry, geology and even biology. The present Astronuclear Physics review focusses primarily on the facets of nuclear physics that are of relevance to astronomy and astrophysics, the theoretical aspects being of special concern here., Comment: 100 pages, 24 figures, accepted for publication in the "Progress in Particle and Nuclear Physics" Journal

Published

2020

55. PANDORA Project for the study of photonuclear reactions below A=60

Author

Tamii, A., Pellegri, L., Söderström, P.-A., Allard, D., Goriely, S., Inakura, T., Khan, E., Kido, E., Kimura, M., Litvinova, E., Nagataki, S., Neumann-Cosel, P. von, Pietralla, N., Shimizu, N., Tsoneva, N., Utsuno, Y., Adachi, S., Adsley, P., Bahini, A., Balabanski, D., Baret, B., Bekker, J. A. C., Binda, S. D., Boicu, E., Bracco, A., Brandherm, I., Brezeanu, M., Brummer, J. W., Camera, F., Crespi, F. C. L., Dalal, R., Donaldson, L. M., Fujikawa, Y., Furuno, T., Haoning, H., Higuchi, R., Honda, Y., Gavrilescu, A., Inoue, A., Isaak, J., Jivan, H., Jones, P., Jongile, S., Just, O., Kawabata, T., Khumalo, T., Kiener, J., Kleemann, J., Kobayashi, N., Koshio, Y., Kuşoğlu, A., Li, K. C. W., Malatji, K. L., Molaeng, R. E., Motoki, H., Murata, M., Netshiya, A. A., Neveling, R., Niina, R., Okamoto, S., Ota, S., Papst, O., Parizot, E., Petruse, T., Reen, M. S., Ring, P., Sakanashi, K., Sideras-Haddad, E., Siem, S., Spall, M., Suda, T., Sudo, T., Taniguchi, Y., Tatischeff, V., Utsunomiya, H., Wang, H., Werner, V., Wibowo, H., Wiedeking, M., Wieland, O., Xu, Y., and Yang, Z. H.

Published

2023

56. Microscopic cross sections: An utopia?

Author

Goriely S., Hilaire S., and Koning A.J.

Subjects

Physics, QC1-999

Abstract

The increasing need for cross sections far from the valley of stability poses a challenge for nuclear reaction models. So far, predictions of cross sections have relied on more or less phenomenological approaches, depending on parameters adjusted to available experimental data or deduced from systematical relations. While such predictions are expected to be reliable for nuclei not too far from the experimentally known regions, it is clearly preferable to use more fundamental approaches, based on sound physical bases, when dealing with very exotic nuclei. Thanks to the high computer power available today, all major ingredients required to model a nuclear reaction can now be (and have been) microscopically (or semi-microscopically) determined starting from the information provided by a nucleon-nucleon effective interaction. We have implemented all these microscopic ingredients in the TALYS nuclear reaction code, and we are now almost able to perform fully microscopic cross section calculations. The quality of these ingredients and the impact of using them instead of the usually adopted phenomenological parameters will be discussed.

Published

2010

57. Soft structures of γ-ray strength functions studied with the Oslo method

Author

Voinov A., Toft H.K., Siem S., Syed N.U.H., Schiller A., Mitchell G.E., Nyhus H.T., Guttormsen M., Lönnroth T., Goriely S., Brger A., Chankova R., Bernstein L.A., Agvaanluvsan U., and Larsen A.C.

Subjects

Physics, QC1-999

Abstract

We present experimental γ-ray strength functions up to Eγ ∼ Sn measured at the Oslo Cyclotron Laboratory for several Sc, V, Mo, and Sn isotopes. For the lighter nuclei, an unexpected enhancement of the strength function at low γ-ray energies has been revealed. This enhancement could potentially have an impact on neutron-capture cross sections for unstable, neutron-rich nuclei. For the Sn isotopes, we observe increased strength around the neutron separation energy Sn.

Published

2010

58. Combinatorial level densities for practical applications

Author

Sin M., Koning A.J., Capote R., Girod M., Hilaire S., and Goriely S.

Subjects

Physics, QC1-999

Abstract

We review our calculated energy-, spin- and parity-dependent nuclear level densities based on the microscopic combinatorial model described in ref. [1]. We show that this model predicts the experimental sand p-wave neutron resonance spacings with a degree of accuracy comparable to that of the best global models available and also provides reasonable description of low energies cumulative number of levels as well as of the experimental data obtained by the Oslo group [2]. We also provide a renormalization recipe which enables to play with the tabulated results for practical applications. Finally, we study the impact of temperature dependent calculation on s-wave neutron resonance spacings.

Published

2010

59. Reference Database for Photon Strength Functions

Author

Goriely, S., Dimitriou, P., Wiedeking, M., Belgya, T., Firestone, R., Kopecky, J., Krticka, M., Plujko, V., Schwengner, R., Siem, S., Utsunomiya, H., Hilaire, S., Peru, S., Cho, Y. S., Filipescu, D. M., Iwamoto, N., Kawano, T., Varlamov, V., and Xu, R.

Subjects

Nuclear Experiment

Abstract

Photon strength functions describing the average response of the nucleus to an electromagnetic probe are key input information in the theoretical modelling of nuclear reactions. Consequently they are important for a wide range of fields such as nuclear structure, nuclear astrophysics, medical isotope production, fission and fusion reactor technologies. They are also sources of information for widely used reaction libraries such as the IAEA Reference Input Parameter Library and evaluated data files such as EGAF. In the past two decades, the amount of reaction gamma-ray data measured to determine photon strength functions has grown rapidly. Different experimental techniques have led to discrepant results and users are faced with the dilemma which (if any) of the divergent data to adopt. We report on a coordinated effort to compile and assess the existing experimental data on photon strength functions from the giant dipole resonance region to energies below the neutron separation energy. The assessment of the discrepant data at energies around or below the neutron separation energy has been possible only in a few cases where adequate information on the model-dependent analysis and estimation of uncertainties was available. In the giant dipole resonance region, we adopt the recommendations of the new IAEA photonuclear data library. We also present global empirical and semi-microscopic models that describe the photon strength functions in the entire energy region and reproduce reasonably well most of the experimental data. The compiled experimental photon strengths and recommended model calculations are available from the PSF database hosted at the IAEA (URL:www-nds.iaea.org/PSFdatabase)., Comment: IAEA Coordinated Research Project on Generating Reference Database for Photon Strength Functions (F41032)

Published

2019

60. IAEA Photonuclear Data Library 2019

Author

Kawano, T., Cho, Y. S., Dimitriou, P., Filipescu, D., Iwamoto, N., Plujko, V., Tao, X., Utsunomiya, H., Varlamov, V., Xu, R., Capote, R., Gheorghe, I., Gorbachenko, O., Jin, Y. L., Renstrøm, T., Stopani, K., Tian, Y., Tveten, G. M., Wang, J. M., Belgya, T., Firestone, R., Goriely, S., Kopecky, J., Krtička, M., Schwengner, R., Siem, S., and Wiedeking, M.

Subjects

Nuclear Theory

Abstract

Photo-induced reaction cross section data are of importance for a variety of current or emerging applications, such as radiation shielding design and radiation transport analyses, calculations of absorbed dose in the human body during radiotherapy, physics and technology of fission reactors (influence of photo-reactions on neutron balance) and fusion reactors (plasma diagnostics and shielding), activation analyses, safeguards and inspection technologies, nuclear waste transmutation, medical isotope production and astrophysical applications. Since the release of the IAEA Photonuclear Data Library in 1999 however, new experimental data as well as new methods to assess the reliability of experimental cross sections have become available. Theoretical models and input parameters used to evaluate photo-induced reactions have improved significantly over the years. In addition, new measurements of partial photoneutron cross sections using mono-energetic photon beams and advanced neutron detection systems have been performed allowing for the validation of the evaluations and assessments of the experimental data. Furthermore, technological advances have led to the construction of new and more powerful gamma-beam facilities, therefore new data needs are emerging. We report our coordinated efforts to address these data needs and present the results of the new evaluations of more than 200 nuclides included in the new updated IAEA Photonuclear Data Library, where the photon energy goes up to 200 MeV. We discuss the new assessment method and make recommendations to the user community in cases where the experimental data are discrepant and the assessments disagree. In addition, in the absence of experimental data, we present model predictions for photo-induced reaction cross section on nuclides of potential interest to medical radioisotope production.

Published

2019

61. $\gamma$-ray Strength Function for Barium Isotopes

Author

Utsunomiya, H., Renstrøm, T., Tveten, G. M., Goriely, S., Ari-izumi, T., Ingeberg, V. W., Kheswa, B. V., Lui, Y. -W., Miyamoto, S., Hilaire, S., Péru, S., and Koning, A. J.

Subjects

Nuclear Experiment

Abstract

Photoneutron cross sections were measured for $^{137}$Ba and $^{138}$Ba at energies below two-neutron threshold using quasi-monochromatic $\gamma$-ray beams produced in laser Compton-scattering at the NewSUBARU synchrotron radiation facility. The photoneutron data are used to constrain the $\gamma$-ray strength function on the basis of the Hartree-Fock-Bogolyubov plus quasi-particle random phase approximation using the Gogny D1M interaction. Supplementing the experimentally constrained $\gamma$-ray strength function with the zero-limit E1 and M1 contributions which are unique to the deexcitation mode, we discuss radiative neutron capture cross sections relevant to the s-process nucleosynthesis of barium isotopes in the vicinity of the neutron magic number 82., Comment: arXiv admin note: substantial text overlap with arXiv:1811.00291, arXiv:1804.07654

Published

2019

62. Unified equations of state for cold non-accreting neutron stars with Brussels-Montreal functionals. I. Role of symmetry energy

Author

Pearson, J. M., Chamel, N., Potekhin, A. Y., Fantina, A. F., Ducoin, C., Dutta, A. K., and Goriely, S.

Subjects

Astrophysics - High Energy Astrophysical Phenomena, Nuclear Theory

Abstract

The theory of the nuclear energy-density functional is used to provide a unified and thermodynamically consistent treatment of all regions of cold non-accreting neutron stars. In order to assess the impact of our lack of complete knowledge of the density dependence of the symmetry energy on the constitution and the global structure of neutron stars, we employ four different functionals. All of them were precision fitted to essentially all the nuclear-mass data with the Hartree-Fock-Bogoliubov method and two different neutron-matter equations of state based on realistic nuclear forces. For each functional, we calculate the composition, the pressure-density relation, and the chemical potentials throughout the star. We show that uncertainties in the symmetry energy can significantly affect the theoretical results for the composition and global structure of neutron stars. To facilitate astrophysical applications, we construct analytic fits to our numerical results., Comment: 36 pages, 31 figures, 29 tables; corrected according to an erratum (2019, accepted)

Published

2019

63. Nuclear level densities and gamma-ray strength functions of $^{180,181,182}$Ta

Author

Brits, C. P., Malatji, K. L., Wiedeking, M., Kheswa, B. V., Goriely, S., Garrote, F. L. Bello, Bleuel, D. L., Giacoppo, F., Gorgen, A., Guttormsen, M., Hadynska-Klek, K., Hagen, T. W., Hilaire, S., Ingeberg, V. W., Jui, H., Klintefjord, M., Larsen, A. C., Majola, S. N. T., Papka, P., Peru, S., Qi, B., Renstrom, T., Rose, S. J., Sahin, E., Siem, S., Tveten, G. M., and Zeiser, F.

Subjects

Nuclear Experiment

Abstract

Particle-$\gamma$ coincidence experiments were performed at the Oslo Cyclotron Laboratory with the $^{181}$Ta(d,X) and $^{181}$Ta($^{3}$He,X) reactions, to measure the nuclear level densities (NLDs) and $\gamma$-ray strength functions ($\gamma$SFs) of $^{180, 181, 182}$Ta using the Oslo method. The Back-shifted Fermi-Gas, Constant Temperature plus Fermi Gas, and Hartree-Fock-Bogoliubov plus Combinatorial models where used for the absolute normalisations of the experimental NLDs at the neutron separation energies. The NLDs and $\gamma$SFs are used to calculate the corresponding $^{181}$Ta(n,$\gamma$) cross sections and these are compared to results from other techniques. The energy region of the scissors resonance strength is investigated and from the data and comparison to prior work it is concluded that the scissors strength splits into two distinct parts. This splitting may allow for the determination of triaxiality and a $\gamma$ deformation of $14.9^{\circ} \pm 1.8^{\circ}$ was determined for $^{181}$Ta.

Published

2019

64. The $\gamma$-ray strength function for Thallium isotopes relevant to the $^{205}$Pb - $^{205}$Tl chronometry

Author

Utsunomiya, H., Renstrøm, T., Tveten, G. M., Goriely, S., Ari-izumi, T., Filipescu, D., Kaur, J., Lui, Y. -W., Luo, W., Miyamoto, S., Larsen, A. C., Hilaire, S., Péru, S., and Koning, A. J.

Subjects

Nuclear Experiment

Abstract

Photoneutron cross sections were measured for $^{203}$Tl and $^{205}$Tl at energies between the one- and two-neutron thresholds using quasi-monochromatic $\gamma$-ray beams produced in laser Compton-scattering at the NewSUBARU synchrotron radiation facility. Our new measurement results in cross sections significantly different from the previously reported bremsstrahlung experiment, leading to rather different GDR parameters, in particular to lower GDR peak energies and higher peak cross sections. The photoneutron data are used to constrain the $\gamma$-ray strength function on the basis of the Hartree-Fock-Bogolyubov plus quasi-particle random phase approximation using the Gogny D1M interaction. Supplementing the experimentally constrained $\gamma$-ray strength function with the zero-limit E1 and M1 contributions for the de-excitation mode, we estimate the Maxwellian-averaged cross section for the s-process branching-point nucleus $^{204}$Tl in the context of the $^{205}$Pb - $^{205}$Tl chronometry., Comment: 8 pages, 10 figures, to be submitted to PRC

Published

2018

65. Determination of the photodisintegration reaction rates involving charged particles: systematical calculations and proposed measurements based on Extreme Light Infrastructure - Nuclear Physics (ELI-NP)

Author

Lan, H. Y., Xu, Y., Luo, W., Balabanski, D. L., Goriely, S., La Cognata, M., Matei, C., Anzalone, A., Chesnevskaya, S., Guardo, G. L., Lattuada, D., Pizzone, R. G., Romano, S., Spitaleri, C., Taffara, A., Tumino, A., and Zhu, Z. C.

Subjects

Nuclear Theory, Astrophysics - Solar and Stellar Astrophysics, Nuclear Experiment

Abstract

Photodisintegration reaction rates involving charged particles are of relevance to the p-process nucleosynthesis that aims at explaining the production of the stable neutron-deficient nuclides heavier than iron. In this study, the cross sections and astrophysical rates of (g,p) and (g,a) reactions for about 3000 target nuclei with 10

Published

2018

66. Photoneutron reaction cross section measurements on 94Mo and 90Zr relevant to the p-process nucleosynthesis

Author

Banu, A., Meekins, E. G., Silano, J. A., Karwowski, H. J., and Goriely, S.

Subjects

Nuclear Experiment

Abstract

The photodisintegration cross sections for the 94Mo({\gamma},n) and 90Zr({\gamma},n) reactions have been experimentally investigated with quasi-monochromatic photon beams at the High Intensity {\gamma}-ray Source (HI{\gamma}S) facility of the Triangle Universities Nuclear Laboratory (TUNL). The energy dependence of the photoneutron reaction cross sections was measured with high precision from the respective neutron emission thresholds up to 13.5 MeV. These measurements contribute to a broader investigation of nuclear reactions relevant to the understanding of the p-process nucleosynthesis. The results are compared with the predictions of Hauser-Feshbach statistical model calculations using two different models for the dipole {\gamma}-ray strength function. The resulting 94Mo({\gamma},n) and 90Zr({\gamma},n) photoneutron stellar reaction rates as a function of temperature in the typical range of interest for the p-process nucleosynthesis show how sensitive the photoneutron stellar reaction rate can be to the experimental data in the vicinity of the neutron threshold.

Published

2018

67. When binaries keep track of recent nucleosynthesis: The Zr - Nb pair in extrinsic stars as an s-process diagnostic

Author

Karinkuzhi, D., Van Eck, S., Jorissen, A., Goriely, S., Siess, L., Merle, T., Escorza, A., Van der Swaelmen, M., Boffin, H. M. J., Masseron, T., Shetye, S., and Plez, B.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Barium stars are s-process enriched giants. They owe their chemical peculiarities to a past mass transfer phase. During which they were polluted by their binary companion, which at the time was an AGB star, but is now an extinct white dwarf. Barium stars are thus ideal targets for understanding and constraining the s-process in low and intermediate-mass AGB stars. We derive the abundances of a large number of heavy elements in order to shed light on the conditions of operation of the neutron source responsible for the production of s-elements in the former companions of the barium stars. Adopting a recently used methodology(Neyskens et al. 2015), we analyse a sample of 18 highly enriched barium stars observed with the high-resolution HERMES spectrograph mounted on the MERCATOR telescope (La Palma). We determine the stellar parameters and abundances using MARCS model atmospheres. In particular, we derive the Nb/Zr ratio which was previously shown to be a sensitive thermometer for the s-process nucleosynthesis. Indeed, in barium stars, $^{93}Zr$ has fully decayed into mono-isotopic $^{93}Nb$ , so Nb/Zr is a measure of the temperature-sensitive $^{93}Zr/Zr$ isotopic ratio. HD 28159, previously classified as K5III and initially selected to serve as a reference cool K star for our abundance analysis, turns out to be enriched in s-process elements, and as such is a new barium star. Four stars, characterised by high nitrogen abundances, also tend to have high [Nb/Zr] and [hs/ls] ratios. The derived Zr and Nb abundances provide more accurate constraints on the s-process neutron source, identified to be $^{13}C(alpha,n)^{16}O$ for barium stars. The comparison with stellar evolution and nucleosynthesis models shows that the investigated barium stars were polluted by a low-mass (2-3 Solar mass) AGB star. HD 100503 is potentially identified as the highest metallicity CEMP-rs star yet discovered., Comment: 25 pages, 20 figures, Accepted for publication in Astronomy and Astrophysics

Published

2018

68. Crustal heating in accreting neutron stars from the nuclear energy-density functional theory. I. Proton shell effects and neutron-matter constraint

Author

Fantina, A. F., Zdunik, J. L., Chamel, N., Pearson, J. M., Haensel, P., and Goriely, S.

Subjects

Astrophysics - High Energy Astrophysical Phenomena, Nuclear Theory

Abstract

Observations of soft X-ray transients in quiescence suggest the existence of heat sources in the crust of accreting neutron stars. Heat is thought to be released by electroweak and nuclear processes triggered by the burying of ashes of X-ray bursts. The heating is studied using a fully quantum approach taking consistently into account nuclear shell effects. We have followed the evolution of ashes made of $^{56}$Fe employing the nuclear energy-density functional theory. Both the outer and inner crusts are described using the same functional, thus ensuring a unified and thermodynamically consistent treatment. To assess the role of the neutron-matter constraint, we have employed the set of accurately calibrated Brussels-Montreal functionals BSk19, BSk20, and BSk21 and for comparison the SLy4 functional. Due to nuclear shell effects, the fully accreted crust is found to be much less stratified than in previous studies. In particular, large regions of the inner crust contain clusters with the magic number $Z=14$. The heat deposited in the outer crust is tightly constrained by experimental atomic mass data. The shallow heating we obtain does not exceed $0.2$~MeV and is therefore not enough to explain the cooling of some soft X-ray transients. The total heat released in the crust is very sensitive to details of the nuclear structure and is predicted to lie in the range from $1.5$~MeV to $1.7$~MeV. The evolution of an accreted matter element and therefore the location of heat sources are governed to a large extent by the existence of nuclear shell closures. Ignoring these effects in the inner crust, the total heat falls to $\sim 0.6$~MeV. The neutron-matter constraint is also found to play a key role. The large amount of heat obtained by Steiner et al. (2012) could thus be traced back to unrealistic neutron-matter equations of state., Comment: 20 pages, 13 figures, submitted to A&A

Published

2018

69. Photoneutron cross sections for Ni isotopes: Toward understanding $(n,\gamma)$ cross sections relevant to the weak s-process nucleosynthesis

Author

Utsunomiya, H., Renstrøm, T., Tveten, G. M., Goriely, S., Katayama, S., Ari-izumi, T., Takenaka, D., Symochko, D., Kheswa, B. V., Ingeberg, V. W., Glodariu, T., Lui, Y. -W., Miyamoto, S., Larsen, A. C., Midtbø, J. E., Görgen, A., Siem, S., Campo, L. Crespo, Guttormsen, M., Hilaire, S., Péru, S., and Koning, A. J.

Subjects

Nuclear Experiment, Nuclear Theory

Abstract

Photoneutron cross sections were measured for $^{58}$Ni, $^{60}$Ni, $^{61}$Ni, and $^{64}$Ni at energies between the one-neutron and two-neutron thresholds using quasi-monochromatic $\gamma$-ray beams produced in laser Compton-scattering at the NewSUBARU synchrotron radiation facility. The new photoneutron data are used to extract the $\gamma$-ray strength function above the neutron threshold complementing the information obtained by the Oslo method below the threshold. We discuss radiative neutron capture cross sections and the Maxwellian-averaged cross sections for Ni isotopes including $^{63}$Ni, a branching point nucleus along the weak s-process path. The cross sections are calculated with the experimentally constrained $\gamma$-ray strength functions from the Hartree-Fock-Bogolyubov plus quasi-particle-random phase approximation based on the Gogny D1M interaction for both $E1$ and $M1$ components and supplemented with the $M1$ upbend., Comment: 9 pages, 7 figures, re-submitted to PRC

Published

2018

70. The gamma-ray strength function of $^{89}$Y and $^{90}$Y

Author

Tveten, G. M., Renstrøm, T., Larsen, A. C., Utsunomiya, H., Stopani, K., Belyshev, S., Guttormsen, M., Ari-izumi, T., Garrote, F. L. Bello, Bleuel, D. L., Byun, Y., Eriksen, T. K., Filipescu, D., Giacoppo, F., Gheorghe, I., Goriely, S., Görgen, A., Harissopulos, S., Katayama, S., Klintefjord, M., Luo, W., Lui, Y. -W., Sahin, E., Schwengner, R., Siem, S., Takenaka, D., Tornyi, T. G., Voinov, A. V., and Wiedeking, M.

Subjects

Nuclear Experiment

Abstract

In this work, we present new data on the $^{89}$Y($\gamma$,n) cross section studied with a quasi-monochromatic photon beam produced at the NewSUBARU synchrotron radiation facility in Japan contributing torwards resolving a long standing discrepancy between existing measurements of this cross section. Results for $\gamma$-ray strength function below threshold obtained by applying the Oslo method to $^{89}$Y($p,p'\gamma$)$^{89}$Y coincidences combined with the $^{89}$Y($\gamma$,n) data this providing experimental data for the $\gamma$-ray strength function of $^{89}$Y for $\gamma$ energies in the range of $\approx 1.6$ Mev to $\approx$ 20 MeV. A low-energy enhancement is seen for $\gamma$-rays below $\approx 2.5$ MeV. Shell-model calculations indicate that this feature is caused by strong, low-energy $M1$ transitions at high excitation energies. The nuclear level density and $\gamma$-ray strength function have been extracted from $^{89}$Y($d,p \gamma$)$^{90}$Y coincidences using the Oslo method. Using the ($\gamma,n$) and ($d,p\gamma$) data as experimental constraints, we have calculated the $^{89}$Y($n,\gamma$)$^{90}$Y cross section with the TALYS reaction code. Our results have been compared with directly measured (n,$\gamma$) cross sections and evaluations. The $N=50$ isotope $^{89}$Y is an important bottleneck in the s-process and the magnitude of the $^{89}$Y(n,$\gamma)$ cross section is key to understanding how s-process stars produce heavy isotopes., Comment: 18 pages (including references) and 16 figures, to be submitted to PRC

Published

2018

71. Verification of detailed balance for $\gamma$ absorption and emission in Dy isotopes

Author

Renstrøm, T., Utsunomiya, H., Nyhus, H. T., Larsen, A. C., Guttormsen, M., Tveten, G. M., Filipescu, D. M., Gheorghe, I., Goriely, S., Hilaire, S., Lui, Y. -W., Midtbø, J. E., Péru, S., Shima, T., Siem, S., and Tesileanu, O.

Subjects

Nuclear Experiment

Abstract

The photo-neutron cross sections of $^{162,163}\rm{Dy}$ have been measured for the first time in an energy region from the neutron threshold ($S_n$) up to $\approx$ $13$~MeV. The ($\gamma$,n) reaction was induced with quasi-monochromatic laser Compton-scattered $\gamma$ rays, produced at the NewSUBARU laboratory. The corresponding $\gamma$-ray strength functions ($\gamma$SF) have been calculated from the photo-neutron cross sections. The data are compared to reanalyzed $\gamma$SFs of $^{160-164}\rm{Dy}$, which are measured below $S_n$. The excellent agreement with the photo-neutron data at $S_n$ confirms the principle of detailed balance. Thus, a complete $\gamma$SF is established covering in total the energy region of 1 MeV $\leq$ E$_{\gamma}$ $\leq$ 13 MeV. These mid-shell well-deformed dysprosium isotopes all show scissors resonances with very similar structures. We find that our data predict the same integrated scissors strength as ($\gamma,\gamma^\prime$) data when integrated over the same energy range, which shows that the scissors mode very likely is consistent with the generalized Brink hypothesis. Finally, using the $\gamma$SFs as input in the reaction code TALYS, we have deduced radiative neutron-capture cross sections and compared them to direct measurements. We find a very good agreement within the uncertainties, which gives further support to the experimentally determined $\gamma$SFs.

Published

2018

72. Reference database for photon strength functions

Author

Goriely, S, Dimitriou, P, Wiedeking, M, Belgya, T, Firestone, R, Kopecky, J, Krtička, M, Plujko, V, Schwengner, R, Siem, S, Utsunomiya, H, Hilaire, S, Péru, S, Cho, YS, Filipescu, DM, Iwamoto, N, Kawano, T, Varlamov, V, and Xu, R

Subjects

Affordable and Clean Energy, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Nuclear & Particles Physics

Abstract

Photon strength functions describing the average response of the nucleus to an electromagnetic probe are key input information in the theoretical modelling of nuclear reactions. Consequently they are important for a wide range of fields such as nuclear structure, nuclear astrophysics, medical isotope production, fission and fusion reactor technologies. They are also sources of information for widely used reaction libraries such as the IAEA Reference Input Parameter Library and evaluated data files such as EGAF. In the past two decades, the amount of reaction gamma-ray data measured to determine photon strength functions has grown rapidly. Different experimental techniques have led to discrepant results and users are faced with the dilemma of which (if any) of the divergent data to adopt. We report on a coordinated effort to compile and assess the existing experimental data on photon strength functions from the giant dipole resonance region to energies below the neutron separation energy. The assessment of the discrepant data at energies around or below the neutron separation energy has been possible only in a few cases where adequate information on the model-dependent analysis and estimation of uncertainties was available. In the giant dipole resonance region, we adopt the recommendations of the new IAEA photonuclear data library. We also present global empirical and semi-microscopic models that describe the photon strength functions in the entire energy region and reproduce reasonably well most of the experimental data. The compiled experimental photon strengths and recommended model calculations are available from the PSF database hosted at the IAEA (http://www-nds.iaea.org/PSFdatabase).

Published

2019

73. Nuclear properties for nuclear astrophysics studies

Author

Goriely, S.

Published

2023

74. Pygmy and core polarization dipole modes in $^{206}$Pb: connecting nuclear structure to stellar nucleosynthesis

Author

Tonchev, A. P., Tsoneva, N., Bhatia, C., Arnold, C. W., Goriely, S., Hammond, S. L., Kelley, J. H., Kwan, E., Lenske, H., Piekarewicz, J., Raut, R., Rusev, G., Shizuma, T., and Tornow, W.

Subjects

Nuclear Experiment, Nuclear Theory

Abstract

A high-resolution study of the electromagnetic response of $^{206}$Pb below the neutron separation energy is performed using a ($\vec{\gamma}$,$\gamma'$) experiment at the HI$\vec{\gamma}$S facility. Nuclear resonance fluorescence with 100% linearly polarized photon beams is used to measure spins, parities, branching ratios, and decay widths of excited states in $^{206}$Pb from $4.9$ to $8.1$MeV. The extracted $\Sigma$$B$(E1)$\uparrow$ and $\Sigma$$B$(M1)$\uparrow$ values for the total electric and magnetic dipole strength below the neutron separation energy are 0.9$\pm$0.2e$^2$fm$^2$ and 8.3$\pm$2.0$\mu_{N}^2$, respectively. These measurements are found to be in very good agreement with the predictions from an energy-density functional (EDF) plus quasiparticle phonon model (QPM). Such a detailed theoretical analysis allows to separate the pygmy dipole resonance from both the tail of the giant dipole resonance and multi-phonon excitations. Combined with earlier photonuclear experiments above the neutron separation energy, one extracts a value for the electric dipole polarizability of $^{206}$Pb of $\alpha_{D}\!=\!122\pm10$mb/MeV. When compared to predictions from both the EDF+QPM and accurately calibrated relativistic EDFs, one deduces a range for the neutron-skin thickness of $R_{\rm skin}^{206}\!=\!0.12$-$0.19$fm and a corresponding range for the slope of the symmetry energy of $L\!=\!48$-$60$MeV. This newly obtained information is also used to estimate the Maxwellian-averaged radiative cross section $^{205}$Pb(n,$\gamma$)$^{206}$Pb at 30keV to be $\sigma\!=\!130\!\pm\!25$mb. The astrophysical impact of this measurement--on both the s-process in stellar nucleosynthesis and on the equation of state of neutron-rich matter--is discussed., Comment: 8 pages and 4 figures. Manuscript accepted for publication in Physics Letters B

Published

2017

75. Quasicontinuum $\gamma$-decay of $^{91,92}$Zr: benchmarking indirect ($n,\gamma$) cross section measurements for the $s$-process

Author

Guttormsen, M., Goriely, S., Larsen, A. C., Görgen, A., Hagen, T. W., Renstrøm, T., Siem, S., Syed, N. U. H., Tagliente, G., Toft, H. K., Utsunomiya, H., Voinov, A. V., and Wikan, K.

Subjects

Nuclear Experiment

Abstract

Nuclear level densities (NLDs) and $\gamma$-ray strength functions ($\gamma$SFs) have been extracted from particle-$\gamma$ coincidences of the $^{92}$Zr($p,p' \gamma$)$^{92}$Zr and $^{92}$Zr($p,d \gamma$)$^{91}$Zr reactions using the Oslo method. The new $^{91,92}$Zr $\gamma$SF data, combined with photonuclear cross sections, cover the whole energy range from $E_{\gamma} \approx 1.5$~MeV up to the giant dipole resonance at $E_{\gamma} \approx 17$~MeV. The wide-range $\gamma$SF data display structures at $E_{\gamma} \approx 9.5$~MeV, compatible with a superposition of the spin-flip $M1$ resonance and a pygmy $E1$ resonance. Furthermore, the $\gamma$SF shows a minimum at $E_{\gamma} \approx 2-3$~MeV and an increase at lower $\gamma$-ray energies. The experimentally constrained NLDs and $\gamma$SFs are shown to reproduce known ($n, \gamma$) and Maxwellian-averaged cross sections for $^{91,92}$Zr using the {\sf TALYS} reaction code, thus serving as a benchmark for this indirect method of estimating ($n, \gamma$) cross sections for Zr isotopes., Comment: 10 pages and 9 figures

Published

2017

76. Microscopic Description of Fission for the r-Process in Neutron Star Mergers

Author

Lemaître, J. -F., Goriely, S., Hilaire, S., Dubray, N., Escher, Jutta, editor, Alhassid, Yoram, editor, Bernstein, Lee A., editor, Brown, David, editor, Fröhlich, Carla, editor, Talou, Patrick, editor, and Younes, Walid, editor

Published

2021

77. γ-Ray Strength Functions and GDR Cross Sections in the IAEA Photonuclear Data Project

Author

Utsunomiya, H., Gheorghe, I., Filipescu, D. M., Stopani, K., Belyshev, S., Renstrøm, T., Tveten, G. M., Fan, G., Wang, H., Goriely, S., Lui, Y.-W., Ari-izumi, T., Miyamoto, S., Varlamov, V., Ishkhanov, B., Larsen, A. C., Siem, S., Escher, Jutta, editor, Alhassid, Yoram, editor, Bernstein, Lee A., editor, Brown, David, editor, Fröhlich, Carla, editor, Talou, Patrick, editor, and Younes, Walid, editor

Published

2021

78. Towards More Predictive Nuclear Reaction Modelling

Author

Hilaire, S., Goriely, S., Escher, Jutta, editor, Alhassid, Yoram, editor, Bernstein, Lee A., editor, Brown, David, editor, Fröhlich, Carla, editor, Talou, Patrick, editor, and Younes, Walid, editor

Published

2021

79. Systematic study of the low-lying electric dipole strength in Sn isotopes and its astrophysical implications

Author

Markova, M., primary, Larsen, A. C., additional, von Neumann-Cosel, P., additional, Litvinova, E., additional, Choplin, A., additional, Goriely, S., additional, Martinet, S., additional, Siess, L., additional, Guttormsen, M., additional, Pogliano, F., additional, and Siem, S., additional

Published

2024

80. The intermediate neutron capture process. V. The i-process in AGB stars with overshoot

Author

Choplin, A., primary, Siess, L., additional, Goriely, S., additional, and Martinet, S., additional

Published

2024

81. Large-scale deformed quasiparticle random-phase approximation calculations of the $\gamma$-ray strength function using the Gogny force

Author

Martini, M., Péru, S., Hilaire, S., Goriely, S., and Lechaftois, F.

Subjects

Nuclear Theory, Astrophysics - High Energy Astrophysical Phenomena, Nuclear Experiment

Abstract

Valuable theoretical predictions of nuclear dipole excitations in the whole chart are of great interest for different nuclear applications, including in particular nuclear astrophysics. Here we present large-scale calculations of the $E1$ $\gamma$-ray strength function obtained in the framework of the axially-symmetric deformed QRPA based on the finite-range Gogny force. This approach is applied to even-even nuclei, the strength function for odd nuclei being derived by interpolation. The convergence with respect to the adopted number of harmonic oscillator shells and the cut-off energy introduced in the 2-quasiparticle (2-$qp$) excitation space is analyzed. The calculations performed with two different Gogny interactions, namely D1S and D1M, are compared. A systematic energy shift of the $E1$ strength is found for D1M relative to D1S, leading to a lower energy centroid and a smaller energy-weighted sum rule for D1M. When comparing with experimental photoabsorption data, the Gogny-QRPA predictions are found to overestimate the giant dipole energy by typically $\sim$2 MeV. Despite the microscopic nature of our self-consistent Hartree-Fock-Bogoliubov plus QRPA calculation, some phenomenological corrections need to be included to take into account the effects beyond the standard 2-$qp$ QRPA excitations and the coupling between the single-particle and low-lying collective phonon degrees of freedom. For this purpose, three prescriptions of folding procedure are considered and adjusted to reproduce experimental photoabsorption data at best. All of them are shown to lead to rather similar predictions of the $E1$ strength, both at low energies and for exotic neutron-rich nuclei. Predictions of $\gamma$-ray strength functions and Maxwellian-averaged neutron capture rates for the whole Sn isotopic chain are also discussed and compared with previous theoretical calculations.

Published

2016

82. Solar r-process-constrained actinide production in neutrino-driven winds of supernovae

Author

Goriely, S. and Janka, H. -Th.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - High Energy Astrophysical Phenomena

Abstract

Long-lived radioactive nuclei play an important role as nucleo-cosmochronometers and as cosmic tracers of nucleosynthetic source activity. In particular nuclei in the actinide region like thorium, uranium, and plutonium can testify to the enrichment of an environment by the still enigmatic astrophysical sources that are responsible for the production of neutron-rich nuclei by the rapid neutron-capture process (r-process). Supernovae and merging neutron-star (NS) or NS-black hole binaries are considered as most likely sources of the r-nuclei. But arguments in favour of one or the other or both are indirect and make use of assumptions; they are based on theoretical models with remaining simplifications and shortcomings. An unambiguous observational determination of a production event is still missing. In order to facilitate searches in this direction, e.g.\ by looking for radioactive tracers in stellar envelopes, the interstellar medium or terrestrial reservoirs, we provide improved theoretical estimates and corresponding uncertainty ranges for the actinide production ($^{232}$Th, $^{235,236,238}$U, $^{237}$Np, $^{244}$Pu, and $^{247}$Cm) in neutrino-driven winds of core-collapse supernovae. Since state-of-the-art supernova models do not yield r-process viable conditions ---but still lack, for example, the effects of strong magnetic fields--- we base our investigation on a simple analytical, Newtonian, adiabatic and steady-state wind model and consider the superposition of a large number of contributing components, whose nucleosynthesis-relevant parameters (mass weight, entropy, expansion time scale, and neutron excess) are constrained by the assumption that the integrated wind nucleosynthesis closely reproduces the solar system distribution of r-process elements. We also test the influence of uncertain nuclear physics., Comment: 10 pages, 5 figures, 2 tables, MNRAS accepted

Published

2016

83. La 137,138,139 (n,γ) cross sections constrained with statistical decay properties of la 138,139,140 nuclei

Author

Kheswa, BV, Wiedeking, M, Brown, JA, Larsen, AC, Goriely, S, Guttormsen, M, Bello Garrote, FL, Bernstein, LA, Bleuel, DL, Eriksen, TK, Giacoppo, F, Görgen, A, Goldblum, BL, Hagen, TW, Koehler, PE, Klintefjord, M, Malatji, KL, Midtbø, JE, Nyhus, HT, Papka, P, Renstrøm, T, Rose, SJ, Sahin, E, Siem, S, and Tornyi, TG

Subjects

nucl-ex

Abstract

The nuclear level densities and γ-ray strength functions of La138,139,140 were measured using the La139(He3,α), La139(He3,He3′), and La139(d,p) reactions. The particle-γ coincidences were recorded with the silicon particle telescope (SiRi) and NaI(Tl) (CACTUS) arrays. In the context of these experimental results, the low-energy enhancement in the A∼140 region is discussed. The La137,138,139(n,γ) cross sections were calculated at s- and p-process temperatures using the experimentally measured nuclear level densities and γ-ray strength functions. Good agreement is found between La139(n,γ) calculated cross sections and previous measurements.

Published

2017

84. La137,138,139(n,γ) cross sections constrained with statistical decay properties of La138,139,140 nuclei

Author

Kheswa, BV, Wiedeking, M, Brown, JA, Larsen, AC, Goriely, S, Guttormsen, M, Garrote, FL Bello, Bernstein, LA, Bleuel, DL, Eriksen, TK, Giacoppo, F, Görgen, A, Goldblum, BL, Hagen, TW, Koehler, PE, Klintefjord, M, Malatji, KL, Midtbø, JE, Nyhus, HT, Papka, P, Renstrøm, T, Rose, SJ, Sahin, E, Siem, S, and Tornyi, TG

Subjects

Nuclear and Plasma Physics, Synchrotrons and Accelerators, Physical Sciences, nucl-ex, Nuclear and plasma physics

Abstract

The nuclear level densities and γ-ray strength functions of La138,139,140 were measured using the La139(He3,α), La139(He3,He3′), and La139(d,p) reactions. The particle-γ coincidences were recorded with the silicon particle telescope (SiRi) and NaI(Tl) (CACTUS) arrays. In the context of these experimental results, the low-energy enhancement in the A∼140 region is discussed. The La137,138,139(n,γ) cross sections were calculated at s- and p-process temperatures using the experimentally measured nuclear level densities and γ-ray strength functions. Good agreement is found between La139(n,γ) calculated cross sections and previous measurements.

Published

2017

85. Low-energy enhancement in the \gamma-ray strength functions of $^{73,74}$Ge

Author

Renstrøm, T., Nyhus, H. -T., Utsumoniya, H., Schwengner, R., Goriely, S., Larsen, A. C., Filipescu, D. M., Gheorghe, I., Bernstein, L. A., Bleuel, D. L., Glodariu, T., Görgen, A., Guttormsen, M., Hagen, T. W., Kheswa, B. V., Lui, Y. -W ., Negi, D., Ruud, I. E., Shima, T., Siem, S., Takahisa, K., Tesileanu, O., Tornyi, T. G., Tveten, G. M., and Wiedeking, M.

Subjects

Nuclear Experiment

Abstract

The $\gamma$-ray strength functions and level densities of $^{73,74}$Ge have been extracted up to the neutron separation energy S$_n$ from particle-$\gamma$ coincidence data using the Oslo method. Moreover, the $\gamma$-ray strength function of $^{74}$Ge above S$_n$ has been determined from photo-neutron measurements, hence these two experiments cover the range of E$_\gamma \approx$ 1-13 MeV for $^{74}$Ge. The obtained data show that both $^{73,74}$Ge display an increase in strength at low $\gamma$ energies. The experimental $\gamma$-ray strength functions are compared with $M1$ strength functions deduced from average $B(M1)$ values calculated within the shell model for a large number of transitions. The observed low-energy enhancements in $^{73,74}$Ge are adopted in the calculations of the $^{72,73}$Ge(n,$\gamma$) cross sections, where there are no direct experimental data. Calculated reaction rates for more neutron-rich germanium isotopes are shown to be strongly dependent on the presence of the low-energy enhancement.

Published

2015

86. Experimentally constrained ($p,\gamma$)$^{89}$Y and ($n,\gamma$)$^{89}$Y reaction rates relevant to the $p$-process nucleosynthesis

Author

Larsen, A. C., Guttormsen, M., Schwengner, R., Bleuel, D. L., Goriely, S., Harissopulos, S., Garrote, F. L. Bello, Byun, Y., Eriksen, T. K., Giacoppo, F., Görgen, A., Hagen, T. W., Klintefjord, M., Renstrøm, T., Rose, S. J., Sahin, E., Siem, S., Tornyi, T. G., Tveten, G. M., Voinov, A. V., and Wiedeking, M.

Subjects

Nuclear Experiment

Abstract

The nuclear level density and the $\gamma$-ray strength function have been extracted for $^{89}$Y, using the Oslo Method on $^{89}$Y($p,p' \gamma$)$^{89}$Y coincidence data. The $\gamma$-ray strength function displays a low-energy enhancement consistent with previous observations in this mass region ($^{93-98}$Mo). Shell-model calculations give support that the observed enhancement is due to strong, low-energy $M1$ transitions at high excitation energies. The data were further used as input for calculations of the $^{88}$Sr($p,\gamma$)$^{89}$Y and $^{88}$Y($n,\gamma$)$^{89}$Y cross sections with the TALYS reaction code. Comparison with cross-section data, where available, as well as with values from the BRUSLIB library, shows a satisfying agreement., Comment: 12 pages, 10 figures, version accepted for publication in Phys. Rev. C

Published

2015

87. Experimental constraints on the $\gamma$-ray strength function in $^{90}$Zr using partial cross sections of the $^{89}$Y(p,$\gamma$)$^{90}$Zr reaction

Author

Netterdon, L., Endres, A., Goriely, S., Mayer, J., Scholz, P., Spieker, M., and Zilges, A.

Subjects

Nuclear Experiment

Abstract

Partial cross sections of the $^{89}$Y(p,$\gamma$)$^{90}$Zr reaction have been measured to investigate the $\gamma$-ray strength function in the neutron-magic nucleus $^{90}$Zr. For five proton energies between $E_p=3.65$ MeV and $E_p=4.70$ MeV, partial cross sections for the population of seven discrete states in $^{90}$Zr have been determined by means of in-beam $\gamma$-ray spectroscopy. Since these $\gamma$-ray transitions are dominantly of $E1$ character, the present measurement allows an access to the low-lying dipole strength in $^{90}$Zr. A $\gamma$-ray strength function based on the experimental data could be extracted, which is used to describe the total and partial cross sections of this reaction by Hauser-Feshbach calculations successfully. Significant differences with respect to previously measured strength functions from photoabsorption data point towards deviations from the Brink-Axel hypothesis relating the photo-excitation and de-excitation strength functions., Comment: 5 pages, 5 figures

Published

2015

88. Cosmic Neutron Star Merger Rate and Gravitational Waves constrained by the R Process Nucleosynthesis

Author

Vangioni, E., Goriely, S., Daigne, F., Francois, P., and Belczynski, K.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

The cosmic evolution of the neutron star merger (NSM) rate can be deduced from the observed cosmic star formation rate. This allows to estimate the rate expected in the horizon of the gravitational wave detectors advanced Virgo and ad LIGO and to compare those rates with independent predictions. In this context, the rapid neutron capture process, or r process, can be used as a constraint assuming NSM is the main astrophysical site for this nucleosynthetic process. We compute the early cosmic evolution of a typical r process element, Europium. Eu yields from NSM are taken from recent nucleosynthesis calculations. The same approach allows to compute the cosmic rate of Core Collapse SuperNovae (CCSN) and the associated evolution of Eu. We find that the bulk of Eu observations at high iron abundance can be rather well fitted by either CCSN or NSM scenarios. However, at lower metallicity, the early Eu cosmic evolution favors NSM as the main astrophysical site for the r process. A comparison between our calculations and spectroscopic observations at very low metallicities allows to constrain the coalescence timescale in the NSM scenario to about 0.1 to 0.2 Gyr. These values are in agreement with the coalescence timescales of some observed binary pulsars. Finally, the cosmic evolution of Eu is used to put constraints on the NSM rate, the merger rate in the horizon of the gravitational wave detectors advanced Virgo/ad LIGO, as well as the expected rate of electromagnetic counterparts to mergers (kilonovae) in large near-infrared surveys., Comment: accepted in MNRAS, 19 pages

Published

2015

89. Indirect Zr Cross Section Measurements for the s-Process

Author

Guttormsen, M., Goriely, S., Larsen, A. C., Görgen, A., Hagen, T. W., Renstrøm, T., Siem, S., Syed, N. U. H., Tagliente, G., Toft, H. K., Utsunomiya, H., Voinov, A. V., Wikan, K., Formicola, Alba, editor, Junker, Matthias, editor, Gialanella, Lucio, editor, and Imbriani, Gianluca, editor

Published

2019

90. Photoneutron Reaction Cross Section Measurements on 94Mo and 90Zr Relevant to the p-Process Nucleosynthesis

Author

Banu, A., Meekins, E. G., Silano, J. A., Karwowski, H. J., Goriely, S., Formicola, Alba, editor, Junker, Matthias, editor, Gialanella, Lucio, editor, and Imbriani, Gianluca, editor

Published

2019

91. IAEA Photonuclear Data Library 2019

Author

Kawano, T., Cho, Y.S., Dimitriou, P., Filipescu, D., Iwamoto, N., Plujko, V., Tao, X., Utsunomiya, H., Varlamov, V., Xu, R., Capote, R., Gheorghe, I., Gorbachenko, O., Jin, Y.L., Renstrøm, T., Sin, M., Stopani, K., Tian, Y., Tveten, G.M., Wang, J.M., Belgya, T., Firestone, R., Goriely, S., Kopecky, J., Krtička, M., Schwengner, R., Siem, S., and Wiedeking, M.

Published

2020

92. Photoneutron emission cross sections for C13

Author

Utsunomiya, H., primary, Goriely, S., additional, Kimura, M., additional, Shimizu, N., additional, Utsuno, Y., additional, Tveten, G. M., additional, Renstrøm, T., additional, Ari-izumi, T., additional, and Miyamoto, S., additional

Published

2024

93. Low-energy enhancement in the γ -ray strength functions of Ge 73,74

Author

Renstrøm, T, Nyhus, HT, Utsunomiya, H, Schwengner, R, Goriely, S, Larsen, AC, Filipescu, DM, Gheorghe, I, Bernstein, LA, Bleuel, DL, Glodariu, T, Görgen, A, Guttormsen, M, Hagen, TW, Kheswa, BV, Lui, YW, Negi, D, Ruud, IE, Shima, T, Siem, S, Takahisa, K, Tesileanu, O, Tornyi, TG, Tveten, GM, and Wiedeking, M

Subjects

nucl-ex

Abstract

The γ-ray strength functions and level densities of Ge73,74 have been extracted up to the neutron-separation energy Sn from particle-γ coincidence data using the Oslo method. Moreover, the γ-ray strength function of Ge74 above Sn has been determined from photoneutron measurements; hence these two experiments cover the range of Eγ≈1-13 MeV for Ge74. The obtained data show that both Ge73,74 display an increase in strength at low γ energies. The experimental γ-ray strength functions are compared with M1 strength functions deduced from average B(M1) values calculated within the shell model for a large number of transitions. The observed low-energy enhancements in Ge73,74 are adopted in the calculations of the Ge72,73(n,γ) cross sections, where there are no direct experimental data. Calculated reaction rates for more neutron-rich germanium isotopes are shown to be strongly dependent on the presence of the low-energy enhancement.

Published

2016

94. Linear response theory and neutrino mean free path using Brussels-Montreal Skyrme functionals

Author

Pastore, A., Martini, M., Davesne, D., Navarro, J., Goriely, S., and Chamel, N.

Subjects

Nuclear Theory

Abstract

The Brussels-Montreal Skyrme functionals have been successful to describe properties of both finite nuclei and infinite homogeneous nuclear matter. In their latest version, these functionals have been equipped with two extra density-dependent terms in order to reproduce simultaneously ground state properties of nuclei and infinite nuclear matter properties while avoiding at the same time the arising of ferromagnetic instabilities. In the present article, we extend our previous results of the linear response theory to include such extra terms at both zero and finite temperature in pure neutron matter. The resulting formalism is then applied to derive the neutrino mean free path. The predictions from the Brussels-Montreal Skyrme functionals are compared with ab-initio methods.

Published

2014

95. Gamow-Teller strength in deformed nuclei within the self-consistent charge-exchange quasi-particle random-phase approximation with the Gogny force

Author

Martini, M., Péru, S., and Goriely, S.

Subjects

Nuclear Theory, Nuclear Experiment

Abstract

The charge-exchange excitations in nuclei are studied within the fully self-consistent proton-neutron quasiparticle random-phase approximation using the finite-range Gogny interaction. No additional parameters beyond those included in the effective nuclear force are included. Axially symmetric deformations are consistently taken into account, both in the description of the ground states and spin-isospin excitations. We focus on the isobaric analog and Gamow-Teller resonances. A comparison of the predicted strength distributions to the existing experimental data is presented and the role of nuclear deformation analyzed. The Gamow-Teller strength is used to estimate the beta-decay half-life of nuclei for which experimental data exist. A satisfactory agreement with experimental half-lives is found and justifies the additional study of the exotic neutron-rich N=82, 126 and 184 isotonic chains of relevance for the r-process nucleosynthesis.

Published

2014

96. The lead discrepancy in intrinsically s-process enriched post-AGB stars in the Magellanic Clouds

Author

De smedt, K., Van Winckel, H., Kamath, D., Karakas, A. I., Siess, L., Goriely, S., and Wood, P.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Context: Our understanding of the s-process nucleosynthesis in asymptotic giant branch (AGB) stars is incomplete. AGB models predict, for example, large overabundances of lead (Pb) compared to other s-process elements in metal-poor low-mass AGB stars. This is indeed observed in some extrinsically enhanced metal-poor stars, but not in all. An extensive study of intrinsically s-process enriched objects is essential for improving our knowledge of the AGB third dredge-up and associated s-process nucleosynthesis. Aims: We compare the spectral abundance analysis of the SMC post-AGB star J004441.04-732136.4 with state-of-the-art AGB model predictions with a main focus on Pb. The low S/N in the Pb line region made the result of our previous study inconclusive. We acquired additional data covering the region of the strongest Pb line. Methods: By carefully complementing re-reduced previous data, with newly acquired UVES optical spectra, we improve the S/N of the spectrum around the strongest Pb line. Therefore, an upper limit for the Pb abundance is estimated from a merged weighted mean spectrum using synthetic spectral modeling. We then compare the abundance results from the combined spectra to predictions of tailored AGB evolutionary models from two independent evolution codes. In addition, we determine upper limits for Pb abundances for three previously studied LMC post-AGB objects. Results: Although theoretical predictions for J004441.04-732136.4 match the s-process distribution up to tungsten (W), the predicted very high Pb abundance is clearly not detected. The three additional LMC post-AGB stars show a similar lack of a very high Pb abundance. Conclusion: From our study, we conclude that none of these low-mass, low-metallicity post-AGB stars of the LMC and SMC are strong Pb producers. This conflicts with current theoretical predictions., Comment: 4 pages, 3 figures

Published

2014

97. Upbend and M1 Scissors Mode in Neutron-rich Nuclei --- Consequences for r-process $(n,\gamma )$ Reaction Rates

Author

Larsen, AC, Goriely, S, Bernstein, LA, Bleuel, DL, Bracco, A, Brown, BA, Camera, F, Eriksen, TK, Frauendorf, S, Giacoppo, F, Guttormsen, M, Görgen, A, Harissopulos, S, Leoni, S, Liddick, SN, Naqvi, F, Nyhus, HT, Rose, SJ, Renstrøm, T, Schwengner, R, Siem, S, Spyrou, A, Tveten, GM, Voinov, AV, and Wiedeking, M

Subjects

Mathematical Sciences, Physical Sciences, Nuclear & Particles Physics, Mathematical sciences, Physical sciences

Abstract

An enhanced probability for low-energy γ-emission (upbend, Eγ

Published

2015

98. Upbend and M1 scissors mode in neutron-rich nuclei - Consequences for r-process (n,γ) reaction rates

Author

Larsen, AC, Goriely, S, Bernstein, LA, Bleuel, DL, Bracco, A, Brown, BA, Camera, F, Eriksen, TK, Frauendorf, S, Giacoppo, F, Guttormsen, M, Görgen, A, Harissopulos, S, Leoni, S, Liddick, SN, Naqvi, F, Nyhus, HT, Rose, SJ, Renstrøm, T, Schwengner, R, Siem, S, Spyrou, A, Tveten, GM, Voinov, AV, and Wiedeking, M

Subjects

Nuclear & Particles Physics, Mathematical Sciences, Physical Sciences

Abstract

An enhanced probability for low-energy γ-emission (upbend, Eγ

Published

2015

99. New fission fragment distributions and r-process origin of the rare-earth elements

Author

Goriely, S., Sida, J. -L., Lemaitre, J. -F., Panebianco, S., Dubray, N., Hilaire, S., Bauswein, A., and Janka, H. -Thomas

Subjects

Astrophysics - Solar and Stellar Astrophysics, Nuclear Experiment, Nuclear Theory

Abstract

Neutron star (NS) merger ejecta offer a viable site for the production of heavy r-process elements with nuclear mass numbers A > 140. The crucial role of fission recycling is responsible for the robustness of this site against many astrophysical uncertainties, but calculations sensitively depend on nuclear physics. In particular the fission fragment yields determine the creation of 110 < A < 170 nuclei. Here we apply a new scission-point model, called SPY, to derive the fission fragment distribution (FFD) of all relevant neutron-rich, fissioning nuclei. The model predicts a doubly asymmetric FFD in the abundant A ~ 278 mass region that is responsible for the final recycling of the fissioning material. Using ejecta conditions based on relativistic NS merger calculations we show that this specific FFD leads to a production of the A ~ 165 rare-earth peak that is nicely compatible with the abundance patterns in the Sun and metal-poor stars. This new finding further strengthens the case of NS mergers as possible dominant origin of r-nuclei with A > 140., Comment: 5 pages, 5 figures; accepted by Phys. Rev. Letters

Published

2013

100. Transitional $\gamma$ strength in Cd isotopes

Author

Larsen, A. C., Ruud, I. E., Bürger, A., Goriely, S., Guttormsen, M., Görgen, A., Hagen, T. W., Harissopulos, S., Nyhus, H. T., Renstrøm, T., Schiller, A., Siem, S., Tveten, G. M., Voinov, A. V., and Wiedeking, M.

Subjects

Nuclear Experiment

Abstract

The level densities and $\gamma$-ray strength functions of $^{105,106,111,112}$Cd have been extracted from particle-$\gamma$ coincidence data using the Oslo method. The level densities are in very good agreement with known levels at low excitation energy. The $\gamma$-ray strength functions display no strong enhancement for low $\gamma$ energies. However, more low-energy strength is apparent for $^{105,106}$Cd than for $^{111,112}$Cd. For $\gamma$ energies above $\approx$ 4 MeV, there is evidence for some extra strength, similar to what has been previously observed for the Sn isotopes. The origin of this extra strength is unclear; it might be due to $E1$ and $M1$ transitions originating from neutron skin oscillations or the spin-flip resonance, respectively., Comment: 10 pages, 11 figures

Published

2013