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Detector characterization for a new $^{12}$C+$^{12}$C reaction study at LUNA
Authors:
R. M. Gesùè,
S. Turkat,
J. Skowroński,
M. Aliotta,
L. Barbieri,
F. Barile,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
M. Campostrini,
F. Casaburo,
F. Cavanna,
T. Chillery,
G. F. Ciani,
P. Colombetti,
A. Compagnucci,
P. Corvisiero,
L. Csedreki,
T. Davinson,
D. Dell'Aquila,
R. Depalo,
A. Di Leva
, et al. (28 additional authors not shown)
Abstract:
The $^{12}$C+$^{12}$C fusion reaction plays a crucial role in stellar evolution, including the occurrence of supernova explosions, and in the synthesis of the chemical elements. However, our understanding of its cross section remains severely deficient, particularly below $E_\textrm{cm}=2.5$\,MeV, the energy range of interest for astrophysics. To address these unresolved issues, the LUNA collabora…
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The $^{12}$C+$^{12}$C fusion reaction plays a crucial role in stellar evolution, including the occurrence of supernova explosions, and in the synthesis of the chemical elements. However, our understanding of its cross section remains severely deficient, particularly below $E_\textrm{cm}=2.5$\,MeV, the energy range of interest for astrophysics. To address these unresolved issues, the LUNA collaboration will conduct a dedicated study of the $^{12}$C+$^{12}$C reaction at the Bellotti Ion Beam Facility (Bellotti IBF) located deep underground within the Gran Sasso National Laboratory (LNGS) in Italy. Based on the combination of passive and active shields, this campaign aims to achieve unprecedented sensitivity in measuring the cross sections of the two key reaction channels, $^{12}$C($^{12}$C,$α$)$^{20}$Ne and $^{12}$C($^{12}$C,$p$)$^{23}$Na in the low-energy regime via $γ$-ray detection. Here, we report on a sensitivity study for the upcoming campaign with a focus on the characterization of two detectors, namely a HPGe detector and a NaI(Tl) array. Furthermore, their intrinsic contamination is thoroughly investigated since this could potentially influence the overall sensitivity. Assuming typical beam intensities of the Bellotti IBF, we will be able to investigate reaction rates significantly below 100 counts per day. In case of the $^{12}$C+$^{12}$C reaction we therefore expect to acquire experimental data well below the current limit of $E_\textrm{cm}=2.1\,$MeV. The results are supported by simulations to highlight the advantageous low-background environment, essential for high-precision nuclear astrophysics studies.
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Submitted 7 January, 2026;
originally announced January 2026.
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Nuclear Physics Mid Term Plan at LNGS
Authors:
R. Buompane,
F. Cavanna,
C. Curceanu,
A. D'Onofrio,
A. Di Leva,
A. Formicola,
L. Gialanella,
C. Gustavino,
G. Imbriani,
M. Junker,
A. Marcianò,
F. Marzaioli,
R. Nania,
F. Napolitano,
K. Piscicchia,
O. Straniero,
C. Abia,
M. Aliotta,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Bruno,
A. Caciolli,
A. Chieffi,
G. Ciani
, et al. (37 additional authors not shown)
Abstract:
The Istituto Nazionale di Fisica Nucleare-Laboratori Nazionali del Gran Sasso (LNGS) is one of the largest underground physics laboratory, a very peculiar environment suited for experiments in Astroparticle Physics, Nuclear Physics and Fundamental Symmetries. The newly established Bellotti Ion Beam facility represents a major advance in the possibilities of studying nuclear processes in an undergr…
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The Istituto Nazionale di Fisica Nucleare-Laboratori Nazionali del Gran Sasso (LNGS) is one of the largest underground physics laboratory, a very peculiar environment suited for experiments in Astroparticle Physics, Nuclear Physics and Fundamental Symmetries. The newly established Bellotti Ion Beam facility represents a major advance in the possibilities of studying nuclear processes in an underground environment. A workshop was organized at LNGS in the framework of the Nuclear Physics Mid Term Plan in Italy, an initiative of the Nuclear Physics Division of the Instituto Nazionale di Fisica Nucleare to discuss the opportunities that will be possible to study in the near future by employing state-of-the-art detection systems. In this report, a detailed discussion of the outcome of the workshop is presented.
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Submitted 22 December, 2025;
originally announced December 2025.
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Improved $S$-factor of the $^{13}$C(p,$γ$)$^{14}$N reaction at $E_{\mathrm{p}}\,=\,$330-740 keV and parameters of resonances at 448 keV and 551 keV
Authors:
J. Skowronski,
E. Masha,
D. Piatti,
M. Aliotta,
D. Bemmerer,
A. Boeltzig,
A. Caciolli,
F. Cavanna,
L. Csedreki,
R. Depalo,
P. Hempel,
M. Hilz,
G. Imbriani,
T. Lossin,
M. Osswald,
B. Poser,
D. Rapagnani,
S. Rümmler,
K. Schmidt,
R. S. Sidhu,
T. Szücs,
A. Tóth,
S. Turkat,
S. Vincent,
S. Werner
, et al. (1 additional authors not shown)
Abstract:
The $^{13}$C(p,$γ$)$^{14}$N reaction is the second reaction of the CNO cycle. This cycle takes place in our Sun and fuels massive, Red, and Asymptotic Giant Branch stars. The $^{13}$C(p,$γ$)$^{14}$N rate affects the final abundances of $^{12,13}$C and $^{19}$F nuclides, with impact on our understanding of the i- and s-process, giant star nucleosynthesis and mixing processes, and ultimately the che…
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The $^{13}$C(p,$γ$)$^{14}$N reaction is the second reaction of the CNO cycle. This cycle takes place in our Sun and fuels massive, Red, and Asymptotic Giant Branch stars. The $^{13}$C(p,$γ$)$^{14}$N rate affects the final abundances of $^{12,13}$C and $^{19}$F nuclides, with impact on our understanding of the i- and s-process, giant star nucleosynthesis and mixing processes, and ultimately the chemical evolution of the Galaxy. Here, we report on a new measurement of the $^{13}$C(p,$γ$)$^{14}$N cross-section, which has been performed at the Felsenkeller shallow-underground laboratory in Dresden (Germany). The present $S$-factor results agree at low energy with LUNA data but are about 20% lower than previous literature data over the whole energy range explored, $E\,=\,$310-680 keV. The narrow resonance corresponding to the 7966.9(5) keV excited state has been investigated and we report a new resonance strength, $ωγ\,=\,$18(2) meV. In addition a new R-matrix fit is presented, from which new parameters for the broad resonance corresponding to the 8062.0(10) keV excited state are derived and a new extrapolation for the total $S$-factor down to zero energy is obtained, $S_{\mathrm{tot}}$(0) = 6.4(4) keV b. Finally a new reaction rate is calculated and reported here.
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Submitted 19 December, 2025;
originally announced December 2025.
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Towards a comprehensive study of the 14N(p,g)15O astrophysical key reaction: Description of the experimental technique including novel target preparation
Authors:
A. Compagnucci,
A. Formicola,
M. Campostrini,
J. Cruz,
M. Aliotta,
C. Ananna,
L. Barbieri,
F. Barile,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
F. Casaburo,
F. Cavanna,
G. F. Ciani,
P. Colombetti,
P. Corvisiero,
L. Csedreki,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes,
F. Ferraro
, et al. (24 additional authors not shown)
Abstract:
While the 14N(p,g)15O reaction plays a key role in the hydrogen-burning processes in various stellar conditions, its reaction rate is not known with sufficient precision. Therefore, the first scientific project at the recently launched Bellotti Ion Beam Facility of the Laboratori Nazionali del Gran Sasso was the measurement of the 14N(p,g)15O reaction cross section in the proton energy range betwe…
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While the 14N(p,g)15O reaction plays a key role in the hydrogen-burning processes in various stellar conditions, its reaction rate is not known with sufficient precision. Therefore, the first scientific project at the recently launched Bellotti Ion Beam Facility of the Laboratori Nazionali del Gran Sasso was the measurement of the 14N(p,g)15O reaction cross section in the proton energy range between 250 and 1500 keV. In this paper, the experimental techniques are summarized with special emphasis on the description of solid state nitrogen target production and characterization. The first results of the reaction yield measured at 55 deg detection angle are also presented.
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Submitted 27 October, 2025;
originally announced October 2025.
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Advances in Radiative Capture Studies at LUNA with a Segmented BGO Detector
Authors:
Jakub Skowronski,
Riccardo Maria Gesuè,
Axel Boeltzig,
Giovanni Francesco Ciani,
Denise Piatti,
David Rapagnani,
Marialuisa Aliotta,
Chemsedinne Ananna,
Francesco Barile,
Daniel Bemmerer,
Andreas Best,
Carlo Broggini,
Carlo Giovanni Bruno,
Antonio Caciolli,
Matteo Campostrini,
Francesca Cavanna,
Paolo Colombetti,
Alessandro Compagnucci,
Piero Corvisiero,
Laszlo Csedreki,
Tom Davinson,
Rosanna Depalo,
Antonino Di Leva,
Zoltan Elekes,
Federico Ferraro
, et al. (21 additional authors not shown)
Abstract:
Studies of charged-particle reactions for low-energy nuclear astrophysics require high sensitivity, which can be achieved by means of detection setups with high efficiency and low backgrounds, to obtain precise measurements in the energy region of interest for stellar scenarios. High-efficiency total absorption spectroscopy is an established and powerful tool for studying radiative capture reactio…
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Studies of charged-particle reactions for low-energy nuclear astrophysics require high sensitivity, which can be achieved by means of detection setups with high efficiency and low backgrounds, to obtain precise measurements in the energy region of interest for stellar scenarios. High-efficiency total absorption spectroscopy is an established and powerful tool for studying radiative capture reactions, particularly if combined with the cosmic background reduction by several orders of magnitude obtained at the Laboratory for Underground Nuclear Astrophysics (LUNA). We present recent improvements in the detection setup with the Bismuth Germanium Oxide (BGO) detector at LUNA, aiming to reduce high-energy backgrounds and to increase the summing detection efficiency. The new design results in enhanced sensitivity of the BGO setup, as we demonstrate and discuss in the context of the first direct measurement of the 65 keV resonance ($E_{x} = 5672$ keV) of the $^{17}$O($p,γ$)$^{18}$F reaction. Moreover, we show two applications of the BGO detector, which exploit its segmentation. In case of complex $γ$-ray cascades, e.g. the de-excitation of $E_{x} = 5672$ keV in $^{18}$F, the BGO segmentation allows to identify and suppress the beam-induced background signals that mimic the sum peak of interest. We demonstrate another new application for such a detector in form of in-situ activation measurements of a reaction with $β^{+}$ unstable product nuclei, e.g., the $^{14}$N($p,γ$)$^{15}$O reaction.
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Submitted 7 October, 2025;
originally announced October 2025.
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Status and future directions for direct cross-section measurements of the 13C(a,n)16O reaction for astrophysics
Authors:
L. Csedreki,
Gy. Gyürky,
D. Rapagnani,
G. F. Ciani,
M. Aliotta,
C. Anannad,
L. Barbieri,
F. Barile,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
F. Casaburom,
F. Cavannak,
P. Colombetti,
A. Compagnucci,
P. Corvisiero,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes,
F. Ferraro,
A. Formicola
, et al. (23 additional authors not shown)
Abstract:
The 13C(a,n)16O reaction is the main neutron source of the s-process taking place in thermally pulsing AGB stars and it is one of the main candidate sources of neutrons for the i-process in the astrophysical sites proposed so far. Therefore, its rate is crucial to understand the production of the nuclei heavier than iron in the Universe. For the first time, the LUNA collaboration was able to measu…
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The 13C(a,n)16O reaction is the main neutron source of the s-process taking place in thermally pulsing AGB stars and it is one of the main candidate sources of neutrons for the i-process in the astrophysical sites proposed so far. Therefore, its rate is crucial to understand the production of the nuclei heavier than iron in the Universe. For the first time, the LUNA collaboration was able to measure the 13C(a,n)16O cross section at Ec.m.=0.23-0.3 MeV drastically reducing the uncertainty of the S(E)-factor in the astrophysically relevant energy range. In this paper, we provide details and critical thoughts about the LUNA measurement and compare them with the current understanding of the 13C(a,n)16O reaction in view of future prospect for higher energy measurements. The two very recent results (from the University of Notre Dame and the JUNA collaboration) published after the LUNA data represent an important step forward. There is, however, still room for a lot of improvement in the experimental study of the 13C(a,n)16O reaction, as emphasized in the present manuscript. We conclude that to provide significantly better constraints on the low-energy extrapolation, experimental data need to be provided over a wide energy range, which overlaps with the energy range of current measurements. Furthermore, future experiments need to focus on the proper target characterisation, the determination of neutron detection efficiency having more nuclear physics input, such as angular distribution of the 13C(a,n)16O reaction below Ea<0.8 MeV and study of nuclear properties of monoenergetic neutron sources and/or via the study of sharp resonances of 13C(a,n)16O. Moreover, comprehensive, multichannel R-matrix analysis with a proper estimate of uncertainty budget of experimental data are still required.
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Submitted 2 October, 2025;
originally announced October 2025.
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Study of the $^{20}$Ne($p,γ$)$^{21}$Na reaction at LUNA
Authors:
A. Caciolli
Abstract:
The NeNa-MgAl cycles are involved in the synthesis of Ne, Na, Mg, and Al isotopes. The $^{20}$Ne($p,γ$)$^{21}$Na (Q = 2431.68 keV) reaction is the first and slowest reaction of the NeNa cycle and it controls the speed at which the entire cycle proceeds. At the state of the art, the uncertainty on the 20Ne(p,γ)21Na reaction rate affects the production of the elements in the NeNa cycle. In particula…
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The NeNa-MgAl cycles are involved in the synthesis of Ne, Na, Mg, and Al isotopes. The $^{20}$Ne($p,γ$)$^{21}$Na (Q = 2431.68 keV) reaction is the first and slowest reaction of the NeNa cycle and it controls the speed at which the entire cycle proceeds. At the state of the art, the uncertainty on the 20Ne(p,γ)21Na reaction rate affects the production of the elements in the NeNa cycle. In particular, in the temperature range from 0.1 GK to 1 GK, the rate is dominated by the 366 keV resonance corresponding to the excited state of EX = 2797.5 keV and by the direct capture component. The present study focus on the study of the 366 keV resonance and the direct capture below 400 keV. At LUNA (Laboratory for Underground Nuclear Astrophysics) the $^{20}$Ne($p,γ$)$^{21}$Na reaction has been measured using the intense proton beam delivered by the LUNA 400 kV accelerator and a windowless differential-pumping gas target. The products of the reaction are detected with two high-purity germanium detectors. The experimental details and preliminary results on the 366 keV resonance and on the direct capture component at very low energies will be shown, together with their possible impact on the $^{20}$Ne($p,γ$)$^{21}$Na reaction rate.
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Submitted 2 October, 2025;
originally announced October 2025.
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Improved direct measurement of low-energy resonances in the $^{21}$Ne(p,$γ$)$^{22}$Na reaction
Authors:
R. S. Sidhu,
F. Casaburo,
E. Masha,
M. Aliotta,
C. Ananna,
L. Barbieri,
F. Barile,
C. Baron,
D. Bemmerer,
A. Best,
R. Biassisi,
A. Boeltzig,
R. Bonnel,
C. Broggini,
C. G. Bruno,
A. Caciolli,
M. Campostrini,
F. Cavanna,
T. Chillery,
G. F. Ciani,
P. Colombetti,
A. Compagnucci,
P. Corvisiero,
L. Csedreki,
T. Davinson
, et al. (35 additional authors not shown)
Abstract:
In the nova temperature range, 0.1 GK $< T <$ 0.4 GK, several low-energy resonances dominate the $^{21}$Ne(p,$γ$)$^{22}$Na reaction rate, which is currently affected by large uncertainties. We present a high-precision study of the resonances at $E^{\rm{lab}}_{\rm{r}}$ = 127.3, 271.4, 272.3, 291.5, and 352.6 keV, measured directly at the Laboratory for Underground Nuclear Astrophysics in Italy. The…
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In the nova temperature range, 0.1 GK $< T <$ 0.4 GK, several low-energy resonances dominate the $^{21}$Ne(p,$γ$)$^{22}$Na reaction rate, which is currently affected by large uncertainties. We present a high-precision study of the resonances at $E^{\rm{lab}}_{\rm{r}}$ = 127.3, 271.4, 272.3, 291.5, and 352.6 keV, measured directly at the Laboratory for Underground Nuclear Astrophysics in Italy. The strengths of the 127.3, 271.4, and 291.5 keV resonances are consistent with previous measurements within 1$σ$. However, for the 272.3 keV and 352.6 keV resonances, we report strength values of (129.9 $\pm$ 5.8) meV and (14.9 $\pm$ 0.8) meV, respectively, more than a factor of 1.5 higher than literature values. In addition, we report on new branching ratios for the 127.3, 272.3, and 352.6 keV resonances, leading to updated decay schemes. Finally, we present a revised thermonuclear reaction rate and investigate its impact on the NeNa nucleosynthesis.
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Submitted 28 May, 2025;
originally announced May 2025.
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Solid Target production for Astrophysical Reasearch: the European target laboratory partnership in ChETEC-INFRA
Authors:
Roberta Spartà,
Alexandra Spiridon,
Rosanna Depalo,
Denise Piatti,
Antonio Massara,
Nicoleta Florea,
Marcel Heine,
Radu-Florin Andrei,
Beyhan Bastin,
Ion Burducea,
Antonio Caciolli,
Matteo Campostrini,
Sandrine Courtin,
Federico Ferraro,
Giovanni Luca Guardo,
Felix Heim,
Decebal Iancu,
Marco La Cognata,
Livio Lamia,
Gaetano Lanzalone,
Eliana Masha,
Paul Mereuta,
Jean Nippert,
Rosario Gianluca Pizzone,
Giuseppe Gabriele Rapisarda
, et al. (6 additional authors not shown)
Abstract:
The joint work of European target laboratories in the ChETEC-INFRA project is presented, to face the new experimental challenges of nuclear astrophysics. In particular, results are presented on innovative targets of 12,13C, 16O, and 19F that were produced, characterized, and, in some cases, tested under beam irradiation. STAR (Solid Targets for Astrophysics Research) is already acting to increase…
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The joint work of European target laboratories in the ChETEC-INFRA project is presented, to face the new experimental challenges of nuclear astrophysics. In particular, results are presented on innovative targets of 12,13C, 16O, and 19F that were produced, characterized, and, in some cases, tested under beam irradiation. STAR (Solid Targets for Astrophysics Research) is already acting to increase collaboration among laboratories, to achieve shared protocols for target production, and to offer a characterization service to the entire nuclear astrophysics community.
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Submitted 22 April, 2025;
originally announced April 2025.
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A Comparative Analysis of R-Matrix Fitting: ${}^{12}$C$(p,γ)$${}^{13}$N as Test Case
Authors:
J. Skowronski,
D. Piatti,
D. Rapagnani,
M. Aliotta,
C. Ananna,
L. Barbieri,
F. Barile,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
M. Campostrini,
F. Casaburo,
F. Cavanna,
G. F. Ciani,
P. Colombetti,
A. Compagnucci,
P. Corvisiero,
L. Csedreki,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes
, et al. (27 additional authors not shown)
Abstract:
In nuclear astrophysics, the accurate determination of nuclear reaction cross sections at astrophysical energies is critical for understanding stellar evolution and nucleosynthesis. This study focuses on the $^{12}$C($p, γ$)$^{13}$N reaction, which takes part in the CNO cycle and is significant for determining the $^{12}$C/$^{13}$C ratio in stellar interiors. Data from various studies, including r…
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In nuclear astrophysics, the accurate determination of nuclear reaction cross sections at astrophysical energies is critical for understanding stellar evolution and nucleosynthesis. This study focuses on the $^{12}$C($p, γ$)$^{13}$N reaction, which takes part in the CNO cycle and is significant for determining the $^{12}$C/$^{13}$C ratio in stellar interiors. Data from various studies, including recent LUNA measurements, reveal high discrepancies in cross section values, underscoring the need for robust fitting approaches. Utilizing the R-matrix theory, we compare different frequentist and Bayesian methodologies for estimating reaction cross sections and their uncertainties. The analysis evaluates the strengths and weaknesses of different statistical techniques, highlighting the importance of systematic uncertainty treatment and the estimate of covariance matrix estimation to enhance the reliability and reproducibility of uncertainty estimates in nuclear astrophysics.
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Submitted 22 February, 2025; v1 submitted 19 February, 2025;
originally announced February 2025.
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Characterization of the LUNA neutron detector array for the measurement of the 13C(a,n)16O reaction
Authors:
L. Csedreki,
G. F. Ciani,
J. Balibrea-Correa,
A. Best,
M. Aliotta,
F. Barile,
D. Bemmerer,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
F. Cavanna,
T. Chillery,
P. Colombetti,
P. Corvisiero,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes,
F. Ferraro,
E. M. Fiore,
A. Formicola,
Zs. Fulop,
G. Gervino,
A. Guglielmetti
, et al. (24 additional authors not shown)
Abstract:
We introduce the LUNA neutron detector array developed for the investigation of the 13C(a,n)16O reaction towards its astrophysical s-process Gamow peak in the low-background environment of the Laboratori Nazionali del Gran Sasso (LNGS). Eighteen 3He counters are arranged in two different configurations (in a vertical and a horizontal orientation) to optimize neutron detection effciency, target han…
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We introduce the LUNA neutron detector array developed for the investigation of the 13C(a,n)16O reaction towards its astrophysical s-process Gamow peak in the low-background environment of the Laboratori Nazionali del Gran Sasso (LNGS). Eighteen 3He counters are arranged in two different configurations (in a vertical and a horizontal orientation) to optimize neutron detection effciency, target handling and target cooling over the investigated energy range Ea;lab = 300 - 400 keV (En = 2.2 - 2.6 MeV in emitted neutron energy). As a result of the deep underground location, the passive shielding of the setup and active background suppression using pulse shape discrimination, we reached a total background rate of 1.23 +- 0.12 counts/hour. This resulted in an improvement of two orders of magnitude over the state of the art allowing a direct measurement of the 13C(a,n)16O cross-section down to Ea;lab = 300 keV. The absolute neutron detection efficiency of the setup was determined using the 51V(p,n)51Cr reaction and an AmBe radioactive source, and completed with a Geant4 simulation. We determined a (34+-3) % and (38+-3) % detection efficiency for the vertical and horizontal configurations, respectively, for En = 2.4 MeV neutrons.
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Submitted 7 November, 2024;
originally announced November 2024.
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First direct measurement of the 64.5 keV resonance strength in $^{17}$O(p,$γ$)$^{18}$F reaction
Authors:
R. M. Gesuè,
G. F. Ciani,
D. Piatti,
A. Boeltzig,
D. Rapagnani,
M. Aliotta,
C. Ananna,
L. Barbieri,
F. Barile,
D. Bemmerer,
A. Best,
C. Broggini,
C. G. Bruno,
A. Caciolli,
M. Campostrini,
F. Casaburo,
F. Cavanna,
P. Colombetti,
A. Compagnucci,
P. Corvisiero,
L. Csedreki,
T. Davinson,
G. M. De Gregorio,
D. Dell'Aquila,
R. Depalo
, et al. (28 additional authors not shown)
Abstract:
The CNO cycle is one of the most important nuclear energy sources in stars. At temperatures of hydrostatic H-burning (20 MK $<$ T $<$ 80 MK) the $^{17}$O(p,$γ$)$^{18}$F reaction rate is dominated by the poorly constrained 64.5~keV resonance. Here we report on the first direct measurements of its resonance strength and of the direct capture contribution at 142 keV, performed with a new high sensiti…
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The CNO cycle is one of the most important nuclear energy sources in stars. At temperatures of hydrostatic H-burning (20 MK $<$ T $<$ 80 MK) the $^{17}$O(p,$γ$)$^{18}$F reaction rate is dominated by the poorly constrained 64.5~keV resonance. Here we report on the first direct measurements of its resonance strength and of the direct capture contribution at 142 keV, performed with a new high sensitivity setup at LUNA. The present resonance strength of $ωγ_{(p, γ)}$\textsuperscript{bare} = (30 $\pm$ 6\textsubscript{stat} $\pm$ 2\textsubscript{syst})~peV is about a factor of 2 higher than the values in literature, leading to a $Γ$\textsubscript{p}\textsuperscript{bare} = (34 $\pm$ 7\textsubscript{stat} $\pm$ 3\textsubscript{syst})~neV, in agreement with LUNA result from the (p,$α$) channel. Such agreement strengthen our understanding of the oxygen isotopic ratios measured in red giant stars and in O-rich presolar grains.
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Submitted 6 August, 2024;
originally announced August 2024.
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First measurement of the low-energy direct capture in 20Ne(p, γ)21Na and improved energy and strength of the Ecm = 368 keV resonance
Authors:
E. Masha,
L. Barbieri,
J. Skowronski,
M. Aliotta,
C. Ananna,
F. Barile,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
M. Campostrini,
F. Casaburo,
F. Cavanna,
G. F. Ciani,
A. Ciapponi,
P. Colombetti,
A. Compagnucci,
P. Corvisiero,
L. Csedreki,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes
, et al. (26 additional authors not shown)
Abstract:
The $\mathrm{^{20}Ne(p, γ)^{21}Na}$ reaction is the slowest in the NeNa cycle and directly affects the abundances of the Ne and Na isotopes in a variety of astrophysical sites. Here we report the measurement of its direct capture contribution, for the first time below $E\rm_{cm} = 352$~keV, and of the contribution from the $E^{\rm }_{cm} = 368$~keV resonance, which dominates the reaction rate at…
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The $\mathrm{^{20}Ne(p, γ)^{21}Na}$ reaction is the slowest in the NeNa cycle and directly affects the abundances of the Ne and Na isotopes in a variety of astrophysical sites. Here we report the measurement of its direct capture contribution, for the first time below $E\rm_{cm} = 352$~keV, and of the contribution from the $E^{\rm }_{cm} = 368$~keV resonance, which dominates the reaction rate at $T=0.03-1.00$~GK. The experiment was performed deep underground at the Laboratory for Underground Nuclear Astrophysics, using a high-intensity proton beam and a windowless neon gas target. Prompt $γ$ rays from the reaction were detected with two high-purity germanium detectors. We obtain a resonance strength $ωγ~=~(0.112 \pm 0.002_{\rm stat}~\pm~0.005_{\rm sys})$~meV, with an uncertainty a factor of $3$ smaller than previous values. Our revised reaction rate is 20\% lower than previously adopted at $T < 0.1$~GK and agrees with previous estimates at temperatures $T \geq 0.1$~GK.
Initial astrophysical implications are presented.
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Submitted 7 November, 2023;
originally announced November 2023.
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New proton-capture rates on carbon isotopes and their impact on the astrophysical $^{12}\mathrm{C}/{}^{13}\mathrm{C}$ ratio
Authors:
J. Skowronski,
A. Boeltzig,
G. F. Ciani,
L. Csedreki,
D. Piatti,
M. Aliotta,
C. Ananna,
F. Barile,
D. Bemmerer,
A. Best,
C. Broggini,
C. G. Bruno,
A. Caciolli,
M. Campostrini,
F. Cavanna,
P. Colombetti,
A. Compagnucci,
P. Corvisiero,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes,
F. Ferraro,
A. Formicola,
Zs. Fülöp
, et al. (21 additional authors not shown)
Abstract:
The ${}^{12}\mathrm{C}/{}^{13}\mathrm{C}$ ratio is a significant indicator of nucleosynthesis and mixing processes during hydrogen burning in stars. Its value mainly depends on the relative rates of the ${}^{12}\mathrm{C}(p,γ){}^{13}\mathrm{N}$ and ${}^{13}\mathrm{C}(p,γ){}^{14}\mathrm{N}$ reactions. Both reactions have been studied at the Laboratory for Underground Nuclear Astrophysics (LUNA) in…
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The ${}^{12}\mathrm{C}/{}^{13}\mathrm{C}$ ratio is a significant indicator of nucleosynthesis and mixing processes during hydrogen burning in stars. Its value mainly depends on the relative rates of the ${}^{12}\mathrm{C}(p,γ){}^{13}\mathrm{N}$ and ${}^{13}\mathrm{C}(p,γ){}^{14}\mathrm{N}$ reactions. Both reactions have been studied at the Laboratory for Underground Nuclear Astrophysics (LUNA) in Italy down to the lowest energies to date ($E_\mathrm{c.m.} = 60\,\mathrm{keV}$) reaching for the first time the high energy tail of hydrogen burning in the shell of giant stars. Our cross sections, obtained with both prompt $γ$-ray detection and activation measurements, are the most precise to date with overall systematic uncertainties of $7-8\%$. Compared with most of the literature, our results are systematically lower, by $25\%$ for the ${}^{12}\mathrm{C}(p,γ){}^{13}\mathrm{N}$ reaction and by $30\%$ for ${}^{13}\mathrm{C}(p,γ){}^{14}\mathrm{N}$. We provide the most precise value up to now of $(3.6 \pm 0.4)$ in the $20-140\,\mathrm{MK}$ range for the lowest possible ${}^{12}\mathrm{C}/{}^{13}\mathrm{C}$ ratio that can be produced during H burning in giant stars.
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Submitted 30 August, 2023;
originally announced August 2023.
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Improved $S$-factor of the $^{12}$C(p,$γ$)$^{13}$N reaction at $E\,=\,$320-620~keV and the 422~keV resonance
Authors:
J. Skowronski,
E. Masha,
D. Piatti,
M. Aliotta,
H. Babu,
D. Bemmerer,
A. Boeltzig,
R. Depalo,
A. Caciolli,
F. Cavanna,
L. Csedreki,
Z. Fülöp,
G. Imbriani,
D. Rapagnani,
S. Rümmler,
K. Schmidt,
R. S. Sidhu,
T. Szücs,
S. Turkat,
A. Yadav
Abstract:
The 12C(p,γ)13N reaction is the onset process of both the CNO and Hot CNO cycles that drive massive star, Red and Asymptotic Giant Branch star and novae nucleosynthesis. The 12C(p,γ)13N rate affects the final abundances of the stable 12,13C nuclides, with ramifications for meteoritic carbon isotopic abundances and the s-process neutron source strength. Here, a new underground measurement of the 12…
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The 12C(p,γ)13N reaction is the onset process of both the CNO and Hot CNO cycles that drive massive star, Red and Asymptotic Giant Branch star and novae nucleosynthesis. The 12C(p,γ)13N rate affects the final abundances of the stable 12,13C nuclides, with ramifications for meteoritic carbon isotopic abundances and the s-process neutron source strength. Here, a new underground measurement of the 12C(p,γ)13N cross-section is reported. The present data, obtained at the Felsenkeller shallow-underground laboratory in Dresden (Germany), encompass the 320-620 keV center of mass energy range to include the wide and poorly constrained E = 422 keV resonance that dominates the rate at high temperatures. This work S-factor results, lower than literature by 25%, are included in a new comprehensive R-matrix fit, and the energy of the 1+ first excited state of 13N is found to be 2369.6(4) keV, with radiative and proton width of 0.49(3) eV and 34.9(2) keV respectively. A new reaction rate, based on present R-matrix fit and extrapolation, is suggested.
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Submitted 15 June, 2023;
originally announced June 2023.
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Active target TPC for study of photonuclear reactions at astrophysical energies
Authors:
M. Kuich,
M. Ćwiok,
W. Dominik,
A. Fijałkowska,
M. Fila,
A. Giska,
Z. Janas,
A. Kalinowski,
K. Kierzkowski,
C. Mazzocchi,
W. Okliński,
M. Zaremba,
D. Grządziel,
J. Lekki,
W. Królas,
A. Kulińska,
A. Kurowski,
W. Janik,
T. Pieprzyca,
Z. Szklarz,
M. Scholz,
M. Turzański,
U. Wiącek,
U. Woźnicka,
A. Caciolli
, et al. (4 additional authors not shown)
Abstract:
A setup designed to study photonuclear reactions at astrophysical energies - an active target Time Projection Chamber was developed and constructed at the Faculty of Physics, University of Warsaw. The device was successfully employed in two experiments at the Institute of Nuclear Physics Polish Academy of Sciences in Cracow, in which γ- and neutron-induced reactions with CO2 gas target were measur…
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A setup designed to study photonuclear reactions at astrophysical energies - an active target Time Projection Chamber was developed and constructed at the Faculty of Physics, University of Warsaw. The device was successfully employed in two experiments at the Institute of Nuclear Physics Polish Academy of Sciences in Cracow, in which γ- and neutron-induced reactions with CO2 gas target were measured. The reaction products were detected and their momenta reconstructed. Preliminary results are shown.
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Submitted 13 March, 2023;
originally announced March 2023.
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First direct limit on the 334 keV resonance strength in the $^{22}$Ne(α,γ)$^{26}$Mg reaction
Authors:
D. Piatti,
E. Masha,
M. Aliotta,
J. Balibrea-Correa,
F. Barile,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
F. Cavanna,
T. Chillery,
G. F. Ciani,
A. Compagnucci,
P. Corvisiero,
L. Csedreki,
T. Davinson,
R. Depalo,
A. di Leva,
Z. Elekes,
F. Ferraro,
E. M. Fiore,
A. Formicola,
Zs. Fülöp
, et al. (22 additional authors not shown)
Abstract:
In stars, the fusion of $^{22}$Ne and $^4$He may produce either $^{25}$Mg, with the emission of a neutron, or $^{26}$Mg and a $γ$ ray. At high temperature, the ($α,n$) channel dominates, while at low temperature, it is energetically hampered. The rate of its competitor, the $^{22}$Ne($α$,$γ$)$^{26}$Mg reaction, and, hence, the minimum temperature for the ($α,n$) dominance, are controlled by many n…
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In stars, the fusion of $^{22}$Ne and $^4$He may produce either $^{25}$Mg, with the emission of a neutron, or $^{26}$Mg and a $γ$ ray. At high temperature, the ($α,n$) channel dominates, while at low temperature, it is energetically hampered. The rate of its competitor, the $^{22}$Ne($α$,$γ$)$^{26}$Mg reaction, and, hence, the minimum temperature for the ($α,n$) dominance, are controlled by many nuclear resonances. The strengths of these resonances have hitherto been studied only indirectly. The present work aims to directly measure the total strength of the resonance at $E$_{r}$\,=\,$334$\,$keV (corresponding to $E$_{x}$\,=\,$10949$\,$keV in $^{26}$Mg). The data reported here have been obtained using high intensity $^4$He$^+$ beam from the INFN LUNA 400 kV underground accelerator, a windowless, recirculating, 99.9% isotopically enriched $^{22}$Ne gas target, and a 4$π$ bismuth germanate summing $γ$-ray detector. The ultra-low background rate of less than 0.5 counts/day was determined using 67 days of no-beam data and 7 days of $^4$He$^+$ beam on an inert argon target. The new high-sensitivity setup allowed to determine the first direct upper limit of 4.0$\,\times\,$10$^{-11}$ eV (at 90% confidence level) for the resonance strength. Finally, the sensitivity of this setup paves the way to study further $^{22}$Ne($α$,$γ$)$^{26}$Mg resonances at higher energy.
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Submitted 7 September, 2022;
originally announced September 2022.
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Direct measurement of the 13C(α,n)16O cross section into the s-process Gamow peak
Authors:
G. F. Ciani,
L. Csedreki,
D. Rapagnani,
M. Aliotta,
J. Balibrea-Correa,
F. Barile,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
F. Cavanna,
T. Chillery,
P. Corvisiero,
S. Cristallo,
T. Davinson,
R. Depalo,
A. DiLeva,
Z. Elekes,
F. Ferraro,
E. Fiore,
A. Formicola,
Zs. Fulop,
G. Gervino
, et al. (23 additional authors not shown)
Abstract:
One of the main neutron sources for the astrophysical s-process is the reaction 13C(α,n)16O, taking place in thermally pulsing Asymptotic Giant Branch stars at temperatures around 90 MK. To model the nucleosynthesis during this process the reaction cross section needs to be known in the 150-230keV energy window (Gamow peak). At these sub-Coulomb energies cross section direct measurements are sever…
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One of the main neutron sources for the astrophysical s-process is the reaction 13C(α,n)16O, taking place in thermally pulsing Asymptotic Giant Branch stars at temperatures around 90 MK. To model the nucleosynthesis during this process the reaction cross section needs to be known in the 150-230keV energy window (Gamow peak). At these sub-Coulomb energies cross section direct measurements are severely affected by the low event rate, making us rely on input from indirect methods and extrapolations from higher-energy direct data. This leads to an uncertainty in the cross section at the relevant energies too high to reliably constrain the nuclear physics input to s-process calculations. We present the results from a new deep-underground measurement of 13C(α,n)16O, covering the energy range 230-300keV, with drastically reduced uncertainties over previous measurements and for the first time providing data directly inside the s-process Gamow peak. Selected stellar models have been computed to estimate the impact of our revised reaction rate. For stars of nearly solar composition, we find sizeable variations of some isotopes, whose production is influenced by the activation of close-by branching points that are sensitive to the neutron density, in particular the two radioactive nuclei 60Fe and 205Pb, as well as 152Gd
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Submitted 1 October, 2021;
originally announced October 2021.
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Re-evaluation of the $^{22}$Ne($α,γ$)$^{26}$Mg and $^{22}$Ne($α,n$)$^{25}$Mg reaction rates
Authors:
Philip Adsley,
Umberto Battino,
Andreas Best,
Antonio Caciolli,
Alessandra Guglielmetti,
Gianluca Imbriani,
Heshani Jayatissa,
Marco La Cognata,
Livio Lamia,
Eliana Masha,
Cristian Massimi,
Sara Palmerini,
Ashley Tattersall,
Raphael Hirschi
Abstract:
The competing $^{22}$Ne($α,γ$)$^{26}$Mg and $^{22}$Ne($α,n$)$^{25}$Mg reactions control the production of neutrons for the weak $s$-process in massive and AGB stars. In both systems, the ratio between the corresponding reaction rates strongly impacts the total neutron budget and strongly influences the final nucleosynthesis. The $^{22}$Ne($α,γ$)$^{26}$Mg and $^{22}$Ne($α,n$)$^{25}$Mg reaction rate…
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The competing $^{22}$Ne($α,γ$)$^{26}$Mg and $^{22}$Ne($α,n$)$^{25}$Mg reactions control the production of neutrons for the weak $s$-process in massive and AGB stars. In both systems, the ratio between the corresponding reaction rates strongly impacts the total neutron budget and strongly influences the final nucleosynthesis. The $^{22}$Ne($α,γ$)$^{26}$Mg and $^{22}$Ne($α,n$)$^{25}$Mg reaction rates was re-evaluated by using newly available information on $^{26}$Mg given by various recent experimental studies. Evaluations of The evaluated $^{22}$Ne($α,γ$)$^{26}$Mg reaction rate remains substantially similar to that of Longland {\it et al.} but, including recent results from Texas A\&M, the $^{22}$Ne($α,n$)$^{25}$Mg reaction rate is lower at a range of astrophysically important temperatures. Stellar models computed with NEWTON and MESA predict decreased production of the weak branch $s$-process due to the decreased efficiency of $^{22}$Ne as a neutron source. Using the new reaction rates in the MESA model results in $^{96}$Zr/$^{94}$Zr and $^{135}$Ba/$^{136}$Ba ratios in much better agreement with the measured ratios from presolar SiC grains.
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Submitted 21 March, 2021; v1 submitted 29 May, 2020;
originally announced May 2020.
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Setup commissioning for an improved measurement of the D(p,gamma)3He cross section at Big Bang Nucleosynthesis energies
Authors:
V. Mossa,
K. Stöckel,
F. Cavanna,
F. Ferraro,
M. Aliotta,
F. Barile,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
L. Csedreki,
T. Chillery,
G. F. Ciani,
P. Corvisiero,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes,
E. M. Fiore,
A. Formicola,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti
, et al. (22 additional authors not shown)
Abstract:
Among the reactions involved in the production and destruction of deuterium during Big Bang Nucleosynthesis, the deuterium-burning D(p,gamma)3He reaction has the largest uncertainty and limits the precision of theoretical estimates of primordial deuterium abundance. Here we report the results of a careful commissioning of the experimental setup used to measure the cross-section of the D(p,gamma)3H…
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Among the reactions involved in the production and destruction of deuterium during Big Bang Nucleosynthesis, the deuterium-burning D(p,gamma)3He reaction has the largest uncertainty and limits the precision of theoretical estimates of primordial deuterium abundance. Here we report the results of a careful commissioning of the experimental setup used to measure the cross-section of the D(p,gamma)3He reaction at the Laboratory for Underground Nuclear Astrophysics of the Gran Sasso Laboratory (Italy). The commissioning was aimed at minimising all sources of systematic uncertainty in the measured cross sections. The overall systematic error achieved (< 3 %) will enable improved predictions of BBN deuterium abundance.
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Submitted 29 April, 2020;
originally announced May 2020.
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A new approach to monitor 13C-targets degradation in situ for 13C(alpha,n)16O cross-section measurements at LUNA
Authors:
G. F. Ciani,
L. Csedreki,
J. Balibrea-Correa,
A. Best,
M. Aliotta,
F. Barile,
D. Bemmerer,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
F. Cavanna,
T. Chillery,
P. Colombetti,
P. Corvisiero,
T. Davinson,
R. Depalo,
A. Di Leva,
L. Di Paolo,
Z. Elekes,
F. Ferraro,
E. M. Fiore,
A. Formicola,
Zs. Fulop,
G. Gervino
, et al. (24 additional authors not shown)
Abstract:
Direct measurements of reaction cross-sections at astrophysical energies often require the use of solid targets able to withstand high ion beam currents for extended periods of time. Thus, monitoring target thickness, isotopic composition, and target stoichiometry during data taking is critical to account for possible target modifications and to reduce uncertainties in the final cross-section resu…
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Direct measurements of reaction cross-sections at astrophysical energies often require the use of solid targets able to withstand high ion beam currents for extended periods of time. Thus, monitoring target thickness, isotopic composition, and target stoichiometry during data taking is critical to account for possible target modifications and to reduce uncertainties in the final cross-section results. A common technique used for these purposes is the Nuclear Resonant Reaction Analysis (NRRA), which however requires that a narrow resonance be available inside the dynamic range of the accelerator used. In cases when this is not possible, as for example the 13C(alpha,n)16O reaction recently studied at low energies at the Laboratory for Underground Nuclear Astrophysics (LUNA) in Italy, alternative approaches must be found. Here, we present a new application of the shape analysis of primary gamma rays emitted by the 13C(p,g)14N radiative capture reaction. This approach was used to monitor 13C target degradation {\em in situ} during the 13C(alpha,n)16O data taking campaign. The results obtained are in agreement with evaluations subsequently performed at Atomki (Hungary) using the NRRA method. A preliminary application for the extraction of the 13C(alpha,n)16O reaction cross-section at one beam energy is also reported.
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Submitted 3 March, 2020; v1 submitted 23 January, 2020;
originally announced January 2020.
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A new study of the $^{10}$B(p,$α_1 γ$)$^{7}$Be reaction from 0.35 to 1.8 MeV
Authors:
A. Caciolli,
R. Depalo,
V. Rigato
Abstract:
The quantification of isotopes content in materials is extremely important in many research and industrial fields. Accurate determination of boron concentration is very critical in semiconductor, superconductor and steel industry, in environmental and medical applications as well as in nuclear and astrophysics research. The detection of B isotopes and of their ratio in synthetic and natural materi…
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The quantification of isotopes content in materials is extremely important in many research and industrial fields. Accurate determination of boron concentration is very critical in semiconductor, superconductor and steel industry, in environmental and medical applications as well as in nuclear and astrophysics research. The detection of B isotopes and of their ratio in synthetic and natural materials may be accomplished by gamma spectroscopy using the $^{10}$B(p,$α_1 γ$)$^7$Be and $^{11}$B(p,$γ$)$^{12}$C reactions at low proton energy. Here, the $^{10}$B(p,$α_1 γ$)$^7$Be cross section is reported in the center of mass energy range 0.35 to 1.8 MeV. The $E_γ$= 429 keV $γ$ rays were detected at 45$^\circ$ and 90$^\circ$ using a NaI(Tl) and an HPGe detectors, respectively. In the presented energy range, previous cross sections data revealed discrepancies and normalisation issues. Existing data are compared to the new absolute measurement and discussed. The present data have been subtracted from a previous measurement of the total cross section to derive the contribution of the $α_0$ channel.
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Submitted 2 October, 2019; v1 submitted 19 August, 2019;
originally announced August 2019.
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Direct capture cross section and the $E_p$ = 71 and 105 keV resonances in the $^{22}$Ne($p,γ$)$^{23}$Na reaction
Authors:
F. Ferraro,
M. P. Takács,
D. Piatti,
F. Cavanna,
R. Depalo,
M. Aliotta,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
T. Chillery,
G. F. Ciani,
P. Corvisiero,
T. Davinson,
G. D'Erasmo,
A. DiLeva,
Z. Elekes,
E. M. Fiore,
A. Formicola,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino
, et al. (19 additional authors not shown)
Abstract:
The $^{22}$Ne($p,γ$)$^{23}$Na reaction, part of the neon-sodium cycle of hydrogen burning, may explain the observed anticorrelation between sodium and oxygen abundances in globular cluster stars. Its rate is controlled by a number of low-energy resonances and a slowly varying non-resonant component. Three new resonances at $E_p$ = 156.2, 189.5, and 259.7 keV have recently been observed and confirm…
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The $^{22}$Ne($p,γ$)$^{23}$Na reaction, part of the neon-sodium cycle of hydrogen burning, may explain the observed anticorrelation between sodium and oxygen abundances in globular cluster stars. Its rate is controlled by a number of low-energy resonances and a slowly varying non-resonant component. Three new resonances at $E_p$ = 156.2, 189.5, and 259.7 keV have recently been observed and confirmed. However, significant uncertainty on the reaction rate remains due to the non-resonant process and to two suggested resonances at $E_p$ = 71 and 105 keV. Here, new $^{22}$Ne($p,γ$)$^{23}$Na data with high statistics and low background are reported. Stringent upper limits of 6$\times$10$^{-11}$ and 7$\times$10$^{-11}$\,eV (90\% confidence level), respectively, are placed on the two suggested resonances. In addition, the off-resonant S-factor has been measured at unprecedented low energy, constraining the contributions from a subthreshold resonance and the direct capture process. As a result, at a temperature of 0.1 GK the error bar of the $^{22}$Ne($p,γ$)$^{23}$Na rate is now reduced by three orders of magnitude.
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Submitted 3 October, 2018;
originally announced October 2018.
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Effect of beam energy straggling on resonant yield in thin gas targets: The cases $^{22}$Ne(p,γ)$^{23}$Na and $^{14}$N(p,γ)$^{15}$O
Authors:
D. Bemmerer,
F. Cavanna,
R. Depalo,
M. Aliotta,
M. Anders,
A. Boeltzig,
C. Broggini,
C. Bruno,
A. Caciolli,
P. Corvisiero,
T. Davinson,
Z. Elekes,
F. Ferraro,
A. Formicola,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyürky,
R. Menegazzo,
V. Mossa,
F. R. Pantaleo,
P. Prati,
D. A. Scott,
O. Straniero
, et al. (3 additional authors not shown)
Abstract:
When deriving resonance strengths using the thick-target yield approximation, for very narrow resonances it may be necessary to take beam energy straggling into account. This applies to gas targets of a few keV width, especially if there is some additional structure in target stoichiometry or detection efficiency. The correction for this effect is shown and tested on recent studies of narrow reson…
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When deriving resonance strengths using the thick-target yield approximation, for very narrow resonances it may be necessary to take beam energy straggling into account. This applies to gas targets of a few keV width, especially if there is some additional structure in target stoichiometry or detection efficiency. The correction for this effect is shown and tested on recent studies of narrow resonances in the $^{22}$Ne(p,γ)$^{23}$Na and $^{14}$N(p,γ)$^{15}$O reactions.
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Submitted 29 June, 2018;
originally announced June 2018.
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A high-efficiency gas target setup for underground experiments, and redetermination of the branching ratio of the 189.5 keV $\mathbf{^{22}Ne(p,γ)^{23}Na}$ resonance
Authors:
F. Ferraro,
M. P. Takács,
D. Piatti,
V. Mossa,
M. Aliotta,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
F. Cavanna,
T. Chillery,
G. F. Ciani,
P. Corvisiero,
L. Csedreki,
T. Davinson,
R. Depalo,
G. D'Erasmo,
A. Di Leva,
Z. Elekes,
E. M. Fiore,
A. Formicola,
Zs. Fülöp,
G. Gervino
, et al. (20 additional authors not shown)
Abstract:
The experimental study of nuclear reactions of astrophysical interest is greatly facilitated by a low-background, high-luminosity setup. The Laboratory for Underground Nuclear Astrophysics (LUNA) 400 kV accelerator offers ultra-low cosmic-ray induced background due to its location deep underground in the Gran Sasso National Laboratory (INFN-LNGS), Italy, and high intensity, 250-500 $μ$A, proton an…
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The experimental study of nuclear reactions of astrophysical interest is greatly facilitated by a low-background, high-luminosity setup. The Laboratory for Underground Nuclear Astrophysics (LUNA) 400 kV accelerator offers ultra-low cosmic-ray induced background due to its location deep underground in the Gran Sasso National Laboratory (INFN-LNGS), Italy, and high intensity, 250-500 $μ$A, proton and $α$ ion beams. In order to fully exploit these features, a high-purity, recirculating gas target system for isotopically enriched gases is coupled to a high-efficiency, six-fold optically segmented bismuth germanate (BGO) $γ$-ray detector. The beam intensity is measured with a beam calorimeter with constant temperature gradient. Pressure and temperature measurements have been carried out at several positions along the beam path, and the resultant gas density profile has been determined. Calibrated $γ$-intensity standards and the well-known $E_p$ = 278 keV $\mathrm{^{14}N(p,γ)^{15}O}$ resonance were used to determine the $γ$-ray detection efficiency and to validate the simulation of the target and detector setup. As an example, the recently measured resonance at $E_p$ = 189.5 keV in the $^{22}$Ne(p,$γ$)$^{23}$Na reaction has been investigated with high statistics, and the $γ$-decay branching ratios of the resonance have been determined.
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Submitted 12 February, 2018;
originally announced February 2018.
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Astrophysical S-factor of the $^{14}\textrm{N(p,}γ\textrm{)}^{15}\textrm{O}$ reaction at 0.4 -- 1.3\,MeV
Authors:
L. Wagner,
S. Akhmadaliev,
M. Anders,
D. Bemmerer,
A. Caciolli,
St. Gohl,
M. Grieger,
A. Junghans,
M. Marta,
F. Munnik,
T. P. Reinhardt,
S. Reinicke,
M. Röder,
K. Schmidt,
R. Schwengner,
M. Serfling,
M. P. Takács,
T. Szücs,
A. Vomiero,
A. Wagner,
K. Zuber
Abstract:
The $^{14}\textrm{N(p,}γ\textrm{)}^{15}\textrm{O}$ reaction is the slowest reaction of the carbon-nitrogen cycle of hydrogen burning and thus determines its rate. The precise knowledge of its rate is required to correctly model hydrogen burning in asymptotic giant branch stars. In addition, it is a necessary ingredient for a possible solution of the solar abundance problem by using the solar…
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The $^{14}\textrm{N(p,}γ\textrm{)}^{15}\textrm{O}$ reaction is the slowest reaction of the carbon-nitrogen cycle of hydrogen burning and thus determines its rate. The precise knowledge of its rate is required to correctly model hydrogen burning in asymptotic giant branch stars. In addition, it is a necessary ingredient for a possible solution of the solar abundance problem by using the solar $^{13}$N and $^{15}$O neutrino fluxes as probes of the carbon and nitrogen abundances in the solar core. After the downward revision of its cross section due to a much lower contribution by one particular transition, capture to the ground state in $^{15}$O, the evaluated total uncertainty is still 8\%, in part due to an unsatisfactory knowledge of the excitation function over a wide energy range. The present work reports precise S-factor data at twelve energies between 0.357-1.292~MeV for the strongest transition, capture to the 6.79~MeV excited state in $^{15}$O, and at ten energies between 0.479-1.202~MeV for the second strongest transition, capture to the ground state in $^{15}$O. An R-matrix fit is performed to estimate the impact of the new data on astrophysical energies. The recently suggested slight enhancement of the 6.79~MeV transition at low energy could not be confirmed. The present extrapolated zero-energy S-factors are $S_{6.79}(0)$~=~1.24$\pm$0.11~keV~barn and $S_{\rm GS}(0)$~=~0.19$\pm$0.05~keV~barn.
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Submitted 29 November, 2017;
originally announced November 2017.
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LUNA: Status and Prospects
Authors:
C. Broggini,
D. Bemmerer,
A. Caciolli,
D. Trezzi
Abstract:
The essential ingredients of nuclear astrophysics are the thermonuclear reactions which shape the life and death of stars and which are responsible for the synthesis of the chemical elements in the Universe. Deep underground in the Gran Sasso Laboratory the cross sections of the key reactions responsible for the hydrogen burning in stars have been measured with two accelerators of 50 and 400 kV vo…
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The essential ingredients of nuclear astrophysics are the thermonuclear reactions which shape the life and death of stars and which are responsible for the synthesis of the chemical elements in the Universe. Deep underground in the Gran Sasso Laboratory the cross sections of the key reactions responsible for the hydrogen burning in stars have been measured with two accelerators of 50 and 400 kV voltage right down to the energies of astrophysical interest. As a matter of fact, the main advantage of the underground laboratory is the reduction of the background. Such a reduction has allowed, for the first time, to measure relevant cross sections at the Gamow energy. The qualifying features of underground nuclear astrophysics are exhaustively reviewed before discussing the current LUNA program which is mainly devoted to the study of the Big-Bang nucleosynthesis and of the synthesis of the light elements in AGB stars and classical novae. The main results obtained during the study of reactions relevant to the Sun are also reviewed and their influence on our understanding of the properties of the neutrino, of the Sun and of the Universe itself is discussed. Finally, the future of LUNA during the next decade is outlined. It will be mainly focused on the study of the nuclear burning stages after hydrogen burning: helium and carbon burning. All this will be accomplished thanks to a new 3.5 MV accelerator able to deliver high current beams of proton, helium and carbon which will start running under Gran Sasso in 2019. In particular, we will discuss the first phase of the scientific case of the 3.5 MV accelerator focused on the study of $^{12}$C+$^{12}$C and of the two reactions which generate free neutrons inside stars: $^{13}$C($α$,n)$^{16}$O and $^{22}$Ne($α$,n)$^{25}$Mg.
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Submitted 30 November, 2017; v1 submitted 25 July, 2017;
originally announced July 2017.
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Origin of meteoritic stardust unveiled by a revised proton-capture rate of $^{17}$O
Authors:
M. Lugaro,
A. I. Karakas,
C. G. Bruno,
M. Aliotta,
L. R. Nittler,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
A. Caciolli,
F. Cavanna,
G. F. Ciani,
P. Corvisiero,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes,
F. Ferraro,
A. Formicola,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyürky,
G. Imbriani
, et al. (12 additional authors not shown)
Abstract:
Stardust grains recovered from meteorites provide high-precision snapshots of the isotopic composition of the stellar environment in which they formed. Attributing their origin to specific types of stars, however, often proves difficult. Intermediate-mass stars of 4-8 solar masses are expected to contribute a large fraction of meteoritic stardust. However, no grains have been found with characteri…
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Stardust grains recovered from meteorites provide high-precision snapshots of the isotopic composition of the stellar environment in which they formed. Attributing their origin to specific types of stars, however, often proves difficult. Intermediate-mass stars of 4-8 solar masses are expected to contribute a large fraction of meteoritic stardust. However, no grains have been found with characteristic isotopic compositions expected from such stars. This is a long-standing puzzle, which points to serious gaps in our understanding of the lifecycle of stars and dust in our Galaxy. Here we show that the increased proton-capture rate of $^{17}$O reported by a recent underground experiment leads to $^{17}$O/$^{16}$O isotopic ratios that match those observed in a population of stardust grains, for proton-burning temperatures of 60-80 million K. These temperatures are indeed achieved at the base of the convective envelope during the late evolution of intermediate-mass stars of 4-8 solar masses, which reveals them as the most likely site of origin of the grains. This result provides the first direct evidence that these stars contributed to the dust inventory from which the Solar System formed.
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Submitted 1 March, 2017;
originally announced March 2017.
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$^{22}$Ne and $^{23}$Na ejecta from intermediate-mass stars: The impact of the new LUNA rate for $^{22}$Ne(p,$γ$)$^{23}$Na
Authors:
A. Slemer,
P. Marigo,
D. Piatti,
M. Aliotta,
D. Bemmerer,
A. Best,
A. Boeltzig,
A. Bressan,
C. Broggini,
C. G. Bruno,
A. Caciolli,
F. Cavanna,
G. F. Ciani,
P. Corvisiero,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes,
F. Ferraro,
A. Formicola,
Zs. F\",
l\",
p,
G. Gervino,
A. Guglielmetti
, et al. (15 additional authors not shown)
Abstract:
We investigate the impact of the new LUNA rate for the nuclear reaction $^{22}$Ne$(p,γ)^{23}$Na on the chemical ejecta of intermediate-mass stars, with particular focus on the thermally-pulsing asymptotic giant branch (TP-AGB) stars that experience hot-bottom burning. To this aim we use the PARSEC and COLIBRI codes to compute the complete evolution, from the pre-main sequence up to the termination…
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We investigate the impact of the new LUNA rate for the nuclear reaction $^{22}$Ne$(p,γ)^{23}$Na on the chemical ejecta of intermediate-mass stars, with particular focus on the thermally-pulsing asymptotic giant branch (TP-AGB) stars that experience hot-bottom burning. To this aim we use the PARSEC and COLIBRI codes to compute the complete evolution, from the pre-main sequence up to the termination of the TP-AGB phase, of a set of stellar models with initial masses in the range $3.0\,M_{\odot} - 6.0\,M_{\odot}$, and metallicities $Z_{\rm i}=0.0005$, $Z_{\rm i}=0.006$, and $Z_{\rm i} = 0.014$. We find that the new LUNA measures have much reduced the nuclear uncertainties of the $^{22}$Ne and $^{23}$Na AGB ejecta, which drop from factors of $\simeq 10$ to only a factor of few for the lowest metallicity models. Relying on the most recent estimations for the destruction rate of $^{23}$Na, the uncertainties that still affect the $^{22}$Ne and $^{23}$Na AGB ejecta are mainly dominated by evolutionary aspects (efficiency of mass-loss, third dredge-up, convection). Finally, we discuss how the LUNA results impact on the hypothesis that invokes massive AGB stars as the main agents of the observed O-Na anti-correlation in Galactic globular clusters. We derive quantitative indications on the efficiencies of key physical processes (mass loss, third dredge-up, sodium destruction) in order to simultaneously reproduce both the Na-rich, O-poor extreme of the anti-correlation, and the observational constraints on the CNO abundance. Results for the corresponding chemical ejecta are made publicly available.
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Submitted 23 November, 2016;
originally announced November 2016.
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The impact of the revised $^{17}$O$(p,α)^{14}$N reaction rate on $^{17}$O stellar abundances and yields
Authors:
O. Straniero,
C. G. Bruno,
M. Aliotta,
A. Best,
A. Boeltzig,
D. Bemmerer,
C. Broggini,
A. Caciolli,
F. Cavanna,
G. F. Ciani,
P. Corvisiero,
S. Cristallo,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes,
F. Ferraro,
A. Formicola,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
G. Gyürky,
G. Imbriani,
M. Junker
, et al. (11 additional authors not shown)
Abstract:
Context. Material processed by the CNO cycle in stellar interiors is enriched in 17O. When mixing processes from the stellar surface reach these layers, as occurs when stars become red giants and undergo the first dredge up, the abundance of 17O increases. Such an occurrence explains the drop of the 16O/17O observed in RGB stars with mass larger than 1.5 M_\solar. As a consequence, the interstella…
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Context. Material processed by the CNO cycle in stellar interiors is enriched in 17O. When mixing processes from the stellar surface reach these layers, as occurs when stars become red giants and undergo the first dredge up, the abundance of 17O increases. Such an occurrence explains the drop of the 16O/17O observed in RGB stars with mass larger than 1.5 M_\solar. As a consequence, the interstellar medium is continuously polluted by the wind of evolved stars enriched in 17O . Aims. Recently, the Laboratory for Underground Nuclear Astrophysics (LUNA) collaboration released an improved rate of the 17O(p,alpha)14N reaction. In this paper we discuss the impact that the revised rate has on the 16O/17O ratio at the stellar surface and on 17O stellar yields. Methods. We computed stellar models of initial mass between 1 and 20 M_\solar and compared the results obtained by adopting the revised rate of the 17O(p,alpha)14N to those obtained using previous rates. Results. The post-first dredge up 16O/17O ratios are about 20% larger than previously obtained. Negligible variations are found in the case of the second and the third dredge up. In spite of the larger 17O(p,alpha)14N rate, we confirm previous claims that an extra-mixing process on the red giant branch, commonly invoked to explain the low carbon isotopic ratio observed in bright low-mass giant stars, marginally affects the 16O/17O ratio. Possible effects on AGB extra-mixing episodes are also discussed. As a whole, a substantial reduction of 17O stellar yields is found. In particular, the net yield of stars with mass ranging between 2 and 20 M_\solar is 15 to 40% smaller than previously estimated. Conclusions. The revision of the 17O(p,alpha)14N rate has a major impact on the interpretation of the 16O/17O observed in evolved giants, in stardust grains and on the 17O stellar yields.
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Submitted 2 November, 2016;
originally announced November 2016.
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Direct measurement of low-energy $^{22}$Ne(p,$γ$)$^{23}$Na resonances
Authors:
R. Depalo,
F. Cavanna,
M. Aliotta,
M. Anders,
D. Bemmerer,
A. Best,
A. Boeltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
G. F. Ciani,
P. Corvisiero,
T. Davinson,
A. Di Leva,
Z. Elekes,
F. Ferraro,
A. Formicola,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyürky,
G. Imbriani,
M. Junker,
R. Menegazzo
, et al. (8 additional authors not shown)
Abstract:
The $^{22}$Ne(p,$γ$)$^{23}$Na reaction is the most uncertain process in the neon-sodium cycle of hydrogen burning. At temperatures relevant for nucleosynthesis in asymptotic giant branch stars and classical novae, its uncertainty is mainly due to a large number of predicted but hitherto unobserved resonances at low energy. Purpose: A new direct study of low energy $^{22}$Ne(p,$γ$)$^{23}$Na resonan…
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The $^{22}$Ne(p,$γ$)$^{23}$Na reaction is the most uncertain process in the neon-sodium cycle of hydrogen burning. At temperatures relevant for nucleosynthesis in asymptotic giant branch stars and classical novae, its uncertainty is mainly due to a large number of predicted but hitherto unobserved resonances at low energy. Purpose: A new direct study of low energy $^{22}$Ne(p,$γ$)$^{23}$Na resonances has been performed at the Laboratory for Underground Nuclear Astrophysics (LUNA), in the Gran Sasso National Laboratory, Italy. Method: The proton capture on $^{22}$Ne was investigated in direct kinematics, delivering an intense proton beam to a $^{22}$Ne gas target. $γ$ rays were detected with two high-purity germanium detectors enclosed in a copper and lead shielding suppressing environmental radioactivity. Results: Three resonances at 156.2 keV ($ωγ$ = (1.48\,$\pm$\,0.10)\,$\cdot$\,10$^{-7}$ eV), 189.5 keV ($ωγ$ = (1.87\,$\pm$\,0.06)\,$\cdot$\,10$^{-6}$ eV) and 259.7 keV ($ωγ$ = (6.89\,$\pm$\,0.16)\,$\cdot$\,10$^{-6}$ eV) proton beam energy, respectively, have been observed for the first time. For the levels at 8943.5, 8975.3, and 9042.4 keV excitation energy corresponding to the new resonances, the $γ$-decay branching ratios have been precisely measured. Three additional, tentative resonances at 71, 105 and 215 keV proton beam energy, respectively, were not observed here. For the strengths of these resonances, experimental upper limits have been derived that are significantly more stringent than the upper limits reported in the literature. Conclusions: Based on the present experimental data and also previous literature data, an updated thermonuclear reaction rate is provided in tabular and parametric form. The new reaction rate is significantly higher than previous evaluations at temperatures of 0.08-0.3 GK.
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Submitted 4 October, 2016;
originally announced October 2016.
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Improved Direct Measurement of the 64.5 keV Resonance Strength in the 17O(p,a)14N Reaction at LUNA
Authors:
C. G. Bruno,
D. A. Scott,
M. Aliotta,
A. Formicola,
A. Best,
A. Boeltzig,
D. Bemmerer,
C. Broggini,
A. Caciolli,
F. Cavanna,
G. F. Ciani,
P. Corvisiero,
T. Davinson,
R. Depalo,
A. Di Leva,
Z. Elekes,
F. Ferraro,
Zs. Fueloep,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyurky,
G. Imbriani,
M. Junker,
R. Menegazzo
, et al. (10 additional authors not shown)
Abstract:
The $^{17}$O(p,$α$)$^{14}$N reaction plays a key role in various astrophysical scenarios, from asymptotic giant branch stars to classical novae. It affects the synthesis of rare isotopes such as $^{17}$O and $^{18}$F, which can provide constraints on astrophysical models. A new direct determination of the $E_{\rm R}~=~64.5$~keV resonance strength performed at the Laboratory for Underground Nuclear…
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The $^{17}$O(p,$α$)$^{14}$N reaction plays a key role in various astrophysical scenarios, from asymptotic giant branch stars to classical novae. It affects the synthesis of rare isotopes such as $^{17}$O and $^{18}$F, which can provide constraints on astrophysical models. A new direct determination of the $E_{\rm R}~=~64.5$~keV resonance strength performed at the Laboratory for Underground Nuclear Astrophysics accelerator has led to the most accurate value to date, $ωγ= 10.0 \pm 1.4_{\rm stat} \pm 0.7_{\rm syst}$~neV, thanks to a significant background reduction underground and generally improved experimental conditions. The (bare) proton partial width of the corresponding state at $E_{\rm x} = 5672$~keV in $^{18}$F is $Γ_{\rm p} = 35 \pm 5_{\rm stat} \pm 3_{\rm syst}$~neV. This width is about a factor of 2 higher than previously estimated thus leading to a factor of 2 increase in the $^{17}$O(p,$α$)$^{14}$N reaction rate at astrophysical temperatures relevant to shell hydrogen-burning in red giant and asymptotic giant branch stars. The new rate implies lower $^{17}$O/$^{16}$O ratios, with important implications on the interpretation of astrophysical observables from these stars.
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Submitted 3 October, 2016;
originally announced October 2016.
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A new study of $^{10}$B(p,$α$)$^{7}$Be reaction at low energies
Authors:
A. Caciolli,
R. Depalo,
C. Broggini,
M. La Cognata,
L. Lamia,
R. Menegazzo,
L. Mou,
S. M. R. Puglia,
V. Rigato,
S. Romano,
C. Rossi Alvarez,
M. L. Sergi,
C. Spitaleri,
A. Tumino
Abstract:
The $^{10}$B(p,$α$)$^{7}$Be reaction is of great interest since it has many applications in different fields of research such as nuclear astrophysics, nuclear physics, and models of new reactors for clean energy generation. This reaction has been studied at the AN2000 accelerator of the INFN National Laboratories of Legnaro (LNL). The total cross section has been measured in a wide energy range (2…
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The $^{10}$B(p,$α$)$^{7}$Be reaction is of great interest since it has many applications in different fields of research such as nuclear astrophysics, nuclear physics, and models of new reactors for clean energy generation. This reaction has been studied at the AN2000 accelerator of the INFN National Laboratories of Legnaro (LNL). The total cross section has been measured in a wide energy range (250 $-$ 1182 keV) by using the activation method. The decays of the $^7$Be nuclei produced by the reaction were measured at the low counting facility of LNL by using two fully shielded high-purity germanium detectors. The present dataset shows a large discrepancy with respect to one of the previous data at the same energies and reduces the total uncertainty to the level of 6\%. An R-matrix calculation has been performed on the present data using the parameters from previous Trojan Horse measurements for the 10 and 500 keV resonances. The present data do not lay on the R-matrix fit in one point suggesting the existence of a $^{11}$C level not observed yet. Further nuclear investigations are needed to confirm this hypothesis.
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Submitted 15 April, 2016;
originally announced April 2016.
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Underground nuclear astrophysics: why and how
Authors:
A. Best,
A. Caciolli,
Zs. Fülöp,
Gy. Gyürky,
M. Laubenstein,
E. Napolitani,
V. Rigato,
V. Roca,
T. Szücs
Abstract:
The goal of nuclear astrophysics is to measure cross sections of nuclear physics reactions of interest in astrophysics. At stars temperatures, these cross sections are very low due to the suppression of the Coulomb barrier. Cosmic ray induced background can seriously limit the determination of reaction cross sections at energies relevant to astrophysical processes and experimental setups should be…
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The goal of nuclear astrophysics is to measure cross sections of nuclear physics reactions of interest in astrophysics. At stars temperatures, these cross sections are very low due to the suppression of the Coulomb barrier. Cosmic ray induced background can seriously limit the determination of reaction cross sections at energies relevant to astrophysical processes and experimental setups should be arranged in order to improve the signal-to-noise ratio. Placing experiments in underground sites, however, reduces this background opening the way towards ultra low cross section determination. LUNA (Laboratory for Underground Nuclear Astrophysics) was pioneer in this sense. Two accelerators were mounted at the INFN National Laboratories of Gran Sasso (LNGS) allowing to study nuclear reactions close to stellar energies. A summary of the relevant technology used, including accelerators, target production and characterisation, and background treatment is given.
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Submitted 2 January, 2016;
originally announced January 2016.
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Three new low-energy resonances in the $^{22}$Ne(p,$γ$)$^{23}$Na reaction
Authors:
F. Cavanna,
R. Depalo,
M. Aliotta,
M. Anders,
D. Bemmerer,
A. Best,
A. Böltzig,
C. Broggini,
C. G. Bruno,
A. Caciolli,
P. Corvisiero,
T. Davinson,
A. di Leva,
Z. Elekes,
F. Ferraro,
A. Formicola,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyürky,
G. Imbriani,
M. Junker,
R. Menegazzo,
V. Mossa
, et al. (9 additional authors not shown)
Abstract:
The $^{22}$Ne(p,$γ$)$^{23}$Na reaction takes part in the neon-sodium cycle of hydrogen burning. This cycle affects the synthesis of the elements between $^{20}$Ne and $^{27}$Al in asymptotic giant branch stars and novae. The $^{22}$Ne(p,$γ$)$^{23}$Na reaction rate is very uncertain because of a large number of unobserved resonances lying in the Gamow window. At proton energies below 400\,keV, only…
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The $^{22}$Ne(p,$γ$)$^{23}$Na reaction takes part in the neon-sodium cycle of hydrogen burning. This cycle affects the synthesis of the elements between $^{20}$Ne and $^{27}$Al in asymptotic giant branch stars and novae. The $^{22}$Ne(p,$γ$)$^{23}$Na reaction rate is very uncertain because of a large number of unobserved resonances lying in the Gamow window. At proton energies below 400\,keV, only upper limits exist in the literature for the resonance strengths. Previous reaction rate evaluations differ by large factors. In the present work, the first direct observations of the $^{22}$Ne(p,$γ$)$^{23}$Na resonances at 156.2, 189.5, and 259.7\,keV are reported. Their resonance strengths have been derived with 2-7\% uncertainty. In addition, upper limits for three other resonances have been greatly reduced. Data were taken using a windowless $^{22}$Ne gas target and high-purity germanium detectors at the Laboratory for Underground Nuclear Astrophysics in the Gran Sasso laboratory of the National Institute for Nuclear Physics, Italy, taking advantage of the ultra-low background observed deep underground. The new reaction rate is a factor of 5 higher than the recent evaluation at temperatures relevant to novae and asymptotic giant branch stars nucleosynthesis.
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Submitted 17 November, 2015;
originally announced November 2015.
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Determination of gamma-ray widths in $^{15}$N using nuclear resonance fluorescence
Authors:
T. Szücs,
D. Bemmerer,
A. Caciolli,
Zs. Fülöp,
R. Massarczyk,
C. Michelagnoli,
T. P. Reinhardt,
R. Schwengner,
M. P. Takács,
C. A. Ur,
A. Wagner,
L. Wagner
Abstract:
The stable nucleus $^{15}$N is the mirror of $^{15}$O, the bottleneck in the hydrogen burning CNO cycle. Most of the $^{15}$N level widths below the proton emission threshold are known from just one nuclear resonance fluorescence (NRF) measurement, with limited precision in some cases. A recent experiment with the AGATA demonstrator array determined level lifetimes using the Doppler Shift Attenuat…
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The stable nucleus $^{15}$N is the mirror of $^{15}$O, the bottleneck in the hydrogen burning CNO cycle. Most of the $^{15}$N level widths below the proton emission threshold are known from just one nuclear resonance fluorescence (NRF) measurement, with limited precision in some cases. A recent experiment with the AGATA demonstrator array determined level lifetimes using the Doppler Shift Attenuation Method (DSAM) in $^{15}$O. As a reference and for testing the method, level lifetimes in $^{15}$N have also been determined in the same experiment. The latest compilation of $^{15}$N level properties dates back to 1991. The limited precision in some cases in the compilation calls for a new measurement in order to enable a comparison to the AGATA demonstrator data. The widths of several $^{15}$N levels have been studied with the NRF method. The solid nitrogen compounds enriched in $^{15}$N have been irradiated with bremsstrahlung. The $γ$-rays following the deexcitation of the excited nuclear levels were detected with four HPGe detectors. Integrated photon-scattering cross sections of ten levels below the proton emission threshold have been measured. Partial gamma-ray widths of ground-state transitions were deduced and compared to the literature. The photon scattering cross sections of two levels above the proton emission threshold, but still below other particle emission energies have also been measured, and proton resonance strengths and proton widths were deduced. Gamma and proton widths consistent with the literature values were obtained, but with greatly improved precision.
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Submitted 27 October, 2015; v1 submitted 19 June, 2015;
originally announced June 2015.
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A new study of the $^{22}$Ne(p,$γ$)$^{23}$Na reaction deep underground: Feasibility, setup, and first observation of the 186 keV resonance
Authors:
F. Cavanna,
R. Depalo,
M. -L. Menzel,
M. Aliotta,
M. Anders,
D. Bemmerer,
C. Broggini,
C. G. Bruno,
A. Caciolli,
P. Corvisiero,
T. Davinson,
A. di Leva,
Z. Elekes,
F. Ferraro,
A. Formicola,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyürky,
G. Imbriani,
M. Junker,
R. Menegazzo,
P. Prati,
C. Rossi Alvarez
, et al. (6 additional authors not shown)
Abstract:
The $^{22}$Ne(p,$γ$)$^{23}$Na reaction takes part in the neon-sodium cycle of hydrogen burning. This cycle is active in asymptotic giant branch stars as well as in novae and contributes to the nucleosythesis of neon and sodium isotopes. In order to reduce the uncertainties in the predicted nucleosynthesis yields, new experimental efforts to measure the $^{22}$Ne(p,$γ$)$^{23}$Na cross section direc…
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The $^{22}$Ne(p,$γ$)$^{23}$Na reaction takes part in the neon-sodium cycle of hydrogen burning. This cycle is active in asymptotic giant branch stars as well as in novae and contributes to the nucleosythesis of neon and sodium isotopes. In order to reduce the uncertainties in the predicted nucleosynthesis yields, new experimental efforts to measure the $^{22}$Ne(p,$γ$)$^{23}$Na cross section directly at the astrophysically relevant energies are needed. In the present work, a feasibility study for a $^{22}$Ne(p,$γ$)$^{23}$Na experiment at the Laboratory for Underground Nuclear Astrophysics (LUNA) 400\,kV accelerator deep underground in the Gran Sasso laboratory, Italy, is reported. The ion beam induced $γ$-ray background has been studied. The feasibility study led to the first observation of the $E_{\rm p}$ = 186\,keV resonance in a direct experiment. An experimental lower limit of 0.12\,$\times$\,10$^{-6}$\,eV has been obtained for the resonance strength. Informed by the feasibility study, a dedicated experimental setup for the $^{22}$Ne(p,$γ$)$^{23}$Na experiment has been developed. The new setup has been characterized by a study of the temperature and pressure profiles. The beam heating effect that reduces the effective neon gas density due to the heating by the incident proton beam has been studied using the resonance scan technique, and the size of this effect has been determined for a neon gas target.
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Submitted 25 November, 2014; v1 submitted 11 November, 2014;
originally announced November 2014.
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A new study of $^{25}$Mg($α$,n)$^{28}$Si angular distributions at $E_α$ = 3 - 5 MeV
Authors:
A. Caciolli,
T. Marchi,
R. Depalo,
S. Appannababu,
N. Blasi,
C. Broggini,
M. Cinausero,
G. Collazuol,
M. Degerlier,
D. Fabris,
F. Gramegna,
M. Leone,
P. Mastinu,
R. Menegazzo,
G. Montagnoli,
C. Rossi Alvarez,
V. Rigato,
O. Wieland
Abstract:
The observation of $^{26}$Al gives us the proof of active nucleosynthesis in the Milky Way. However the identification of the main producers of $^{26}$Al is still a matter of debate. Many sites have been proposed, but our poor knowledge of the nuclear processes involved introduces high uncertainties. In particular, the limited accuracy on the $^{25}$Mg($α$,n)$^{28}$Si reaction cross section has be…
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The observation of $^{26}$Al gives us the proof of active nucleosynthesis in the Milky Way. However the identification of the main producers of $^{26}$Al is still a matter of debate. Many sites have been proposed, but our poor knowledge of the nuclear processes involved introduces high uncertainties. In particular, the limited accuracy on the $^{25}$Mg($α$,n)$^{28}$Si reaction cross section has been identified as the main source of nuclear uncertainty in the production of $^{26}$Al in C/Ne explosive burning in massive stars, which has been suggested to be the main source of $^{26}$Al in the Galaxy. We studied this reaction through neutron spectroscopy at the CN Van de Graaff accelerator of the Legnaro National Laboratories. Thanks to this technique we are able to discriminate the ($α$,n) events from possible contamination arising from parasitic reactions. In particular, we measured the neutron angular distributions at 5 different beam energies (between 3 and 5 MeV) in the \ang{17.5}-\ang{106} laboratory system angular range. The presented results disagree with the assumptions introduced in the analysis of a previous experiment.
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Submitted 4 September, 2014;
originally announced September 2014.
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Strength of the $E_{\text{p}}$=1.842 MeV resonance in the $^{40}$Ca(p,$γ$)$^{41}$Sc reaction revisited
Authors:
Konrad Schmidt,
Shavkat Akhmadaliev,
Michael Anders,
Daniel Bemmerer,
Antonio Caciolli,
Mirco Dietz,
Zoltán Elekes,
Arnd R. Junghans,
Marie-Luise Menzel,
Ronald Schwengner,
Andreas Wagner,
Kai Zuber
Abstract:
The strength of the $E_{\rm p} = 1.842$ MeV resonance in the $^{40}$Ca(p,$γ$)$^{41}$Sc reaction is determined with two different methods: First, by an absolute strength measurement using calcium hydroxide targets, and second, relative to the well-determined strength of the resonance triplet at $E_α$ = 4.5 MeV in the $^{40}$Ca($α$,$γ$)$^{44}$Ti reaction. The present new value of…
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The strength of the $E_{\rm p} = 1.842$ MeV resonance in the $^{40}$Ca(p,$γ$)$^{41}$Sc reaction is determined with two different methods: First, by an absolute strength measurement using calcium hydroxide targets, and second, relative to the well-determined strength of the resonance triplet at $E_α$ = 4.5 MeV in the $^{40}$Ca($α$,$γ$)$^{44}$Ti reaction. The present new value of $ωγ=(0.192\pm0.017)$ eV is 37% (equivalent to $3.5σ$) higher than the evaluated literature value. In addition, the ratio of the strengths of the 1.842 MeV $^{40}$Ca(p,$γ$)$^{41}$Sc and 4.5 MeV $^{40}$Ca($α$,$γ$)$^{44}$Ti resonances has been determined to be $0.0229\pm0.0018$. The newly corrected strength of the 1.842-MeV resonance can be used in the future as a normalization point for experiments with calcium targets.
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Submitted 8 April, 2014;
originally announced April 2014.
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The resonance triplet at E_alpha = 4.5 MeV in the 40Ca(alpha,gamma)44Ti reaction
Authors:
Konrad Schmidt,
Shavkat Akhmadaliev,
Michael Anders,
Daniel Bemmerer,
Konstanze Boretzky,
Antonio Caciolli,
Detlev Degering,
Mirco Dietz,
Rugard Dressler,
Zoltán Elekes,
Zsolt Fülöp,
György Gyürky,
Roland Hannaske,
Arnd R. Junghans,
Michele Marta,
Marie-Luise Menzel,
Frans Munnik,
Dorothea Schumann,
Ronald Schwengner,
Tamás Szücs,
Andreas Wagner,
Dmitry Yakorev,
Kai Zuber
Abstract:
The 40Ca(alpha,gamma)44Ti reaction is believed to be the main production channel for the radioactive nuclide 44Ti in core-collapse supernovae. Radiation from decaying 44Ti has been observed so far for two supernova remnants, and a precise knowledge of the 44Ti production rate may help improve supernova models. The 40Ca(alpha,gamma)44Ti astrophysical reaction rate is determined by a number of narro…
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The 40Ca(alpha,gamma)44Ti reaction is believed to be the main production channel for the radioactive nuclide 44Ti in core-collapse supernovae. Radiation from decaying 44Ti has been observed so far for two supernova remnants, and a precise knowledge of the 44Ti production rate may help improve supernova models. The 40Ca(alpha,gamma)44Ti astrophysical reaction rate is determined by a number of narrow resonances. Here, the resonance triplet at E_alpha = 4497, 4510, and 4523 keV is studied both by activation, using an underground laboratory for the gamma counting, and by in-beam gamma spectrometry. The target properties are determined by elastic recoil detection analysis and by nuclear reactions. The strengths of the three resonances are determined to omega gamma = (0.92+-0.20), (6.2+-0.5), and (1.32+-0.24) eV, respectively, a factor of two more precise than before. The strengths of this resonance triplet may be used in future works as a point of reference. In addition, the present new data directly affect the astrophysical reaction rate at relatively high temperatures, above 3.5 GK.
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Submitted 24 July, 2013;
originally announced July 2013.
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A multivariate spatial interpolation of airborne γ-ray data using the geological constraints
Authors:
E. Guastaldi,
M. Baldoncini,
G. P. Bezzon,
C. Broggini,
G. P. Buso,
A. Caciolli,
Carmignani L.,
I. Callegari,
T. Colonna,
K. Dule,
G. Fiorentini,
M. Kaçeli Xhixha,
F. Mantovani,
G. Massa,
R. Menegazzo,
L. Mou,
C. Rossi Alvarez,
V. Strati,
G. Xhixha,
A. Zanon
Abstract:
In this paper we present maps of K, eU, and eTh abundances of Elba Island (Italy) obtained with a multivariate spatial interpolation of airborne γ-ray data using the constraints of the geologic map. The radiometric measurements were performed by a module of four NaI(Tl) crystals of 16 L mounted on an autogyro. We applied the collocated cokriging (CCoK) as a multivariate estimation method for inter…
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In this paper we present maps of K, eU, and eTh abundances of Elba Island (Italy) obtained with a multivariate spatial interpolation of airborne γ-ray data using the constraints of the geologic map. The radiometric measurements were performed by a module of four NaI(Tl) crystals of 16 L mounted on an autogyro. We applied the collocated cokriging (CCoK) as a multivariate estimation method for interpolating the primary under-sampled airborne γ-ray data considering the well-sampled geological information as ancillary variables. A random number has been assigned to each of 73 geological formations identified in the geological map at scale 1:10,000. The non-dependency of the estimated results from the random numbering process has been tested for three distinct models. The experimental cross-semivariograms constructed for radioelement-geology couples show well-defined co-variability structures for both direct and crossed variograms. The high statistical correlations among K, eU, and eTh measurements are confirmed also by the same maximum distance of spatial autocorrelation. Combining the smoothing effects of probabilistic interpolator and the abrupt discontinuities of the geological map, the results show a distinct correlation between the geological formation and radioactivity content. The contour of Mt. Capanne pluton can be distinguished by high K, eU and eTh abundances, while different degrees of radioactivity content identify the tectonic units. A clear anomaly of high K content in the Mt. Calamita promontory confirms the presence of felsic dykes and hydrothermal veins not reported in our geological map. Although we assign a unique number to each geological formation, the method shows that the internal variability of the radiometric data is not biased by the multivariate interpolation.
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Submitted 20 June, 2013;
originally announced June 2013.
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Neutron-induced background by an alpha-beam incident on a deuterium gas target and its implications for the study of the 2H(alpha,gamma)6Li reaction at LUNA
Authors:
M. Anders,
D. Trezzi,
A. Bellini,
M. Aliotta,
D. Bemmerer,
C. Broggini,
A. Caciolli,
H. Costantini,
P. Corvisiero,
T. Davinson,
Z. Elekes,
M. Erhard,
A. Formicola,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyürky,
M. Junker,
A. Lemut,
M. Marta,
C. Mazzocchi,
R. Menegazzo,
P. Prati,
C. Rossi Alvarez
, et al. (4 additional authors not shown)
Abstract:
The production of the stable isotope Li-6 in standard Big Bang nucleosynthesis has recently attracted much interest. Recent observations in metal-poor stars suggest that a cosmological Li-6 plateau may exist. If true, this plateau would come in addition to the well-known Spite plateau of Li-7 abundances and would point to a predominantly primordial origin of Li-6, contrary to the results of standa…
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The production of the stable isotope Li-6 in standard Big Bang nucleosynthesis has recently attracted much interest. Recent observations in metal-poor stars suggest that a cosmological Li-6 plateau may exist. If true, this plateau would come in addition to the well-known Spite plateau of Li-7 abundances and would point to a predominantly primordial origin of Li-6, contrary to the results of standard Big Bang nucleosynthesis calculations. Therefore, the nuclear physics underlying Big Bang Li-6 production must be revisited. The main production channel for Li-6 in the Big Bang is the 2H(alpha,gamma)6Li reaction. The present work reports on neutron-induced effects in a high-purity germanium detector that were encountered in a new study of this reaction. In the experiment, an α-beam from the underground accelerator LUNA in Gran Sasso, Italy, and a windowless deuterium gas target are used. A low neutron flux is induced by energetic deuterons from elastic scattering and, subsequently, the 2H(d,n)3He reaction. Due to the ultra-low laboratory neutron background at LUNA, the effect of this weak flux of 2-3 MeV neutrons on well-shielded high-purity germanium detectors has been studied in detail. Data have been taken at 280 and 400 keV alpha-beam energy and for comparison also using an americium-beryllium neutron source.
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Submitted 30 January, 2013;
originally announced January 2013.
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Impact of a revised $^{25}$Mg(p,$γ$)$^{26}$Al reaction rate on the operation of the Mg-Al cycle
Authors:
O. Straniero,
G. Imbriani,
F. Strieder,
D. Bemmerer,
C. Broggini,
A. Caciolli,
P. Corvisiero,
H. Costantini,
S. Cristallo,
A. DiLeva,
A. Formicola,
Z. Elekes,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyürky,
M. Junker,
A. Lemut,
B. Limata,
M. Marta,
C. Mazzocchi,
R. Menegazzo,
L. Piersanti,
P. Prati
, et al. (6 additional authors not shown)
Abstract:
Proton captures on Mg isotopes play an important role in the Mg-Al cycle active in stellar H-burning regions. In particular, low-energy nuclear resonances in the $^{25}$Mg(p,$γ$)$^{26}$Al reaction affect the production of radioactive $^{26}$Al$^{gs}$ as well as the resulting Mg/Al abundance ratio. Reliable estimations of these quantities require precise measurements of the strengths of low-energy…
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Proton captures on Mg isotopes play an important role in the Mg-Al cycle active in stellar H-burning regions. In particular, low-energy nuclear resonances in the $^{25}$Mg(p,$γ$)$^{26}$Al reaction affect the production of radioactive $^{26}$Al$^{gs}$ as well as the resulting Mg/Al abundance ratio. Reliable estimations of these quantities require precise measurements of the strengths of low-energy resonances. Based on a new experimental study performed at LUNA, we provide revised rates of the $^{25}$Mg(p,$γ$)$^{26}$Al$^{gs}$ and the $^{25}$Mg(p,$γ$)$^{26}$Al$^{m}$ reactions with corresponding uncertainties. In the temperature range 50 to 150 MK, the new recommended rate of the $^{26}$Al$^{m}$ production is up to 5 times higher than previously assumed. In addition, at T$=100$ MK, the revised total reaction rate is a factor of 2 higher. Note that this is the range of temperature at which the Mg-Al cycle operates in an H-burning zone. The effects of this revision are discussed. Due to the significantly larger $^{25}$Mg(p,$γ$)$^{26}$Al$^{m}$ rate, the estimated production of $^{26}$Al$^{gs}$ in H-burning regions is less efficient than previously obtained. As a result, the new rates should imply a smaller contribution from Wolf-Rayet stars to the galactic $^{26}$Al budget. Similarly, we show that the AGB extra-mixing scenario does not appear able to explain the most extreme values of $^{26}$Al/$^{27}$Al, i.e. $>10^{-2}$, found in some O-rich presolar grains. Finally, the substantial increase of the total reaction rate makes the hypothesis of a self-pollution by massive AGBs a more robust explanation for the Mg-Al anticorrelation observed in Globular-Cluster stars.
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Submitted 28 November, 2012;
originally announced November 2012.
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First Direct Measurement of the ^{17}O(p,γ)^{18}F Reaction Cross-Section at Gamow Energies for Classical Novae
Authors:
D. A. Scott,
A. Caciolli,
A. DiLeva,
A. Formicola,
M. Aliotta,
M. Anders,
D. Bemmerer,
C. Broggini,
M. Campeggio,
P. Corvisiero,
Z. Elekes,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyürky,
G. Imbriani,
M. Junker,
M. Laubenstein,
R. Menegazzo,
M. Marta,
E. Napolitani,
P. Prati,
V. Rigato,
V. Roca
, et al. (7 additional authors not shown)
Abstract:
Classical novae are important contributors to the abundances of key isotopes, such as the radioactive ^{18}F, whose observation by satellite missions could provide constraints on nucleosynthesis models in novae. The ^{17}O(p,γ)^{18}F reaction plays a critical role in the synthesis of both oxygen and fluorine isotopes but its reaction rate is not well determined because of the lack of experimental…
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Classical novae are important contributors to the abundances of key isotopes, such as the radioactive ^{18}F, whose observation by satellite missions could provide constraints on nucleosynthesis models in novae. The ^{17}O(p,γ)^{18}F reaction plays a critical role in the synthesis of both oxygen and fluorine isotopes but its reaction rate is not well determined because of the lack of experimental data at energies relevant to novae explosions. In this study, the reaction cross section has been measured directly for the first time in a wide energy range Ecm = 200 - 370 keV appropriate to hydrogen burning in classical novae. In addition, the E=183 keV resonance strength, ωγ=1.67\pm0.12 \mueV, has been measured with the highest precision to date. The uncertainty on the ^{17}O(p,γ)^{18}F reaction rate has been reduced by a factor of 4, thus leading to firmer constraints on accurate models of novae nucleosynthesis.
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Submitted 24 October, 2012;
originally announced October 2012.
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Preparation and characterisation of isotopically enriched Ta$_2$O$_5$ targets for nuclear astrophysics studies
Authors:
A. Caciolli,
D. A. Scott,
A. Di Leva,
A. Formicola,
M. Aliotta,
M. Anders,
A. Bellini,
D. Bemmerer,
C. Broggini,
M. Campeggio,
P. Corvisiero,
R. Depalo,
Z. Elekes,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyürky,
G. Imbriani,
M. Junker,
M. Marta,
R. Menegazzo,
E. Napolitani,
P. Prati,
V. Rigato
, et al. (11 additional authors not shown)
Abstract:
The direct measurement of reaction cross sections at astrophysical energies often requires the use of solid targets of known thickness, isotopic composition, and stoichiometry that are able to withstand high beam currents for extended periods of time. Here, we report on the production and characterisation of isotopically enriched Ta$_2$O$_5$ targets for the study of proton-induced reactions at the…
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The direct measurement of reaction cross sections at astrophysical energies often requires the use of solid targets of known thickness, isotopic composition, and stoichiometry that are able to withstand high beam currents for extended periods of time. Here, we report on the production and characterisation of isotopically enriched Ta$_2$O$_5$ targets for the study of proton-induced reactions at the Laboratory for Underground Nuclear Astrophysics facility of the Laboratori Nazionali del Gran Sasso. The targets were prepared by anodisation of tantalum backings in enriched water (up to 66% in $^{17}$O and up to 96% in $^{18}$O). Special care was devoted to minimising the presence of any contaminants that could induce unwanted background reactions with the beam in the energy region of astrophysical interest. Results from target characterisation measurements are reported, and the conclusions for proton capture measurements with these targets are drawn.
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Submitted 1 October, 2012;
originally announced October 2012.
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The worldwide NORM production and a fully automated gamma-ray spectrometer for their characterization
Authors:
G. Xhixha,
GP. Bezzon,
C. Broggini,
GP. Buso,
A. Caciolli,
I. Callegari,
S. De Bianchi,
G. Fiorentini,
E. Guastaldi,
M. Kaçeli Xhixha,
F. Mantovani,
G. Massa,
R. Menegazzo,
L. Mou,
A. Pasquini,
C. Rossi Alvarez,
M. Shyti
Abstract:
Materials containing radionuclides of natural origin, which is modified by human made processes and being subject to regulation because of their radioactivity are known as NORM. We present a brief review of the main categories of non-nuclear industries together with the levels of activity concentration in feed raw materials, products and waste, including mechanisms of radioisotope enrichments. The…
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Materials containing radionuclides of natural origin, which is modified by human made processes and being subject to regulation because of their radioactivity are known as NORM. We present a brief review of the main categories of non-nuclear industries together with the levels of activity concentration in feed raw materials, products and waste, including mechanisms of radioisotope enrichments. The global management of NORM shows a high level of complexity, mainly due to different degrees of radioactivity enhancement and the huge amount of worldwide waste production. The future tendency of guidelines concerning environmental protection will require both a systematic monitoring based on the ever-increasing sampling and high performance of gamma ray spectroscopy. On the ground of these requirements a new low background fully automated high-resolution gamma-ray spectrometer MCA_Rad has been developed. The design of Pb and Cu shielding allowed to reach a background reduction of two order of magnitude with respect to laboratory radioactivity. A severe lowering of manpower cost is obtained through a fully automation system, which enables up to 24 samples to be measured without any human attendance. Two coupled HPGe detectors increase the detection efficiency, performing accurate measurements on sample volume (180 cc) with a reduction of sample transport cost of material. Details of the instrument calibration method are presented. MCA_Rad system can measure in less than one hour a typical NORM sample enriched in U and Th with some hundreds of Bq/kg, with an overall uncertainty less than 5%. Quality control of this method has been tested. Measurements of certified reference materials RGK-1, RGU-2 and RGTh-1 containing concentrations of K, U and Th comparable to NORM have been performed, resulting an overall relative discrepancy of 5% among central values within the reported uncertainty.
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Submitted 24 April, 2012;
originally announced April 2012.
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The 25Mg(p,g)Al reaction at low astrophysical energies
Authors:
LUNA Collaboration,
F. Strieder,
B. Limata,
A. Formicola,
G. Imbriani,
M. Junker,
D. Bemmerer,
A. Best,
C. Broggini,
A. Caciolli,
P. Corvisiero,
H. Costantini,
A. DiLeva,
Z. Elekes,
Zs. Fülöp,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyürky,
A. Lemut,
M. Marta,
C. Mazzocchi,
R. Menegazzo,
P. Prati,
V. Roca
, et al. (6 additional authors not shown)
Abstract:
In the present work we report on a new measurement of resonance strengths in the reaction 25Mg(p,gamma)26Al at E_cm= 92 and 189 keV. This study was performed at the LUNA facility in the Gran Sasso underground laboratory using a 4pi BGO summing crystal. For the first time the 92 keV resonance was directly observed and a resonance strength omega-gamma=(2.9+/-0.6)x10E-10 eV was determined. Additional…
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In the present work we report on a new measurement of resonance strengths in the reaction 25Mg(p,gamma)26Al at E_cm= 92 and 189 keV. This study was performed at the LUNA facility in the Gran Sasso underground laboratory using a 4pi BGO summing crystal. For the first time the 92 keV resonance was directly observed and a resonance strength omega-gamma=(2.9+/-0.6)x10E-10 eV was determined. Additionally, the gamma-ray branchings and strength of the 189 keV resonance were studied with a high resolution HPGe detector yielding an omega-gamma value in agreement with the BGO measurement, but 20% larger compared to previous works.
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Submitted 14 December, 2011;
originally announced December 2011.
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A new FSA approach for in situ $γ$-ray spectroscopy
Authors:
A. Caciolli,
M. Baldoncini,
G. P. Bezzon,
C. Broggini,
G. P. Buso,
I. Callegari,
T. Colonna,
G. Fiorentini,
E. Guastaldi,
F. Mantovani,
G. Massa,
R. Menegazzo,
L. Mou,
C. Rossi Alvarez,
M. Shyti,
A. Zanon,
G. Xhixha
Abstract:
An increasing demand of environmental radioactivity monitoring comes both from the scientific community and from the society. This requires accurate, reliable and fast response preferably from portable radiation detectors. Thanks to recent improvements in the technology, $γ$-spectroscopy with sodium iodide scintillators has been proved to be an excellent tool for in-situ measurements for the ident…
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An increasing demand of environmental radioactivity monitoring comes both from the scientific community and from the society. This requires accurate, reliable and fast response preferably from portable radiation detectors. Thanks to recent improvements in the technology, $γ$-spectroscopy with sodium iodide scintillators has been proved to be an excellent tool for in-situ measurements for the identification and quantitative determination of $γ$-ray emitting radioisotopes, reducing time and costs. Both for geological and civil purposes not only $^{40}$K, $^{238}$U, and $^{232}$Th have to be measured, but there is also a growing interest to determine the abundances of anthropic elements, like $^{137}$Cs and $^{131}$I, which are used to monitor the effect of nuclear accidents or other human activities.
The Full Spectrum Analysis (FSA) approach has been chosen to analyze the $γ$-spectra. The Non Negative Least Square (NNLS) and the energy calibration adjustment have been implemented in this method for the first time in order to correct the intrinsic problem related with the $χ^2$ minimization which could lead to artifacts and non physical results in the analysis.
A new calibration procedure has been developed for the FSA method by using in situ $γ$-spectra instead of calibration pad spectra. Finally, the new method has been validated by acquiring $γ$-spectra with a 10.16 cm x 10.16 cm sodium iodide detector in 80 different sites in the Ombrone basin, in Tuscany. The results from the FSA method have been compared with the laboratory measurements by using HPGe detectors on soil samples collected in the different sites, showing a satisfactory agreement between them. In particular, the $^{137}$Cs isotopes has been implemented in the analysis since it has been found not negligible during the in-situ measurements.
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Submitted 7 November, 2011;
originally announced November 2011.
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Revision of the 15N(p,γ)16O reaction rate and oxygen abundance in H-burning zones
Authors:
A. Caciolli,
C. Mazzocchi,
V. Capogrosso,
D. Bemmerer,
C. Broggini,
P. Corvisiero,
H. Costantini,
Z. Elekes,
A. Formicola,
Zs. Fulop,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyurky,
G. Imbriani,
M. Junker,
A. Lemut,
M. Marta,
R. Menegazzo,
S. Palmerini,
P. Prati,
V. Roca,
C. Rolfs,
C. Rossi Alvarez,
E. Somorjai
, et al. (5 additional authors not shown)
Abstract:
The NO cycle takes place in the deepest layer of a H-burning core or shell, when the temperature exceeds T {\simeq} 30 {\cdot} 106 K. The O depletion observed in some globular cluster giant stars, always associated with a Na enhancement, may be due to either a deep mixing during the RGB (red giant branch) phase of the star or to the pollution of the primordial gas by an early population of massive…
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The NO cycle takes place in the deepest layer of a H-burning core or shell, when the temperature exceeds T {\simeq} 30 {\cdot} 106 K. The O depletion observed in some globular cluster giant stars, always associated with a Na enhancement, may be due to either a deep mixing during the RGB (red giant branch) phase of the star or to the pollution of the primordial gas by an early population of massive AGB (asymptotic giant branch) stars, whose chemical composition was modified by the hot bottom burning. In both cases, the NO cycle is responsible for the O depletion. The activation of this cycle depends on the rate of the 15N(p,γ)16O reaction. A precise evaluation of this reaction rate at temperatures as low as experienced in H-burning zones in stellar interiors is mandatory to understand the observed O abundances. We present a new measurement of the 15N(p,γ)16O reaction performed at LUNA covering for the first time the center of mass energy range 70-370 keV, which corresponds to stellar temperatures between 65 {\cdot} 106 K and 780 {\cdot}106 K. This range includes the 15N(p,γ)16O Gamow-peak energy of explosive H-burning taking place in the external layer of a nova and the one of the hot bottom burning (HBB) nucleosynthesis occurring in massive AGB stars. With the present data, we are also able to confirm the result of the previous R-matrix extrapolation. In particular, in the temperature range of astrophysical interest, the new rate is about a factor of 2 smaller than reported in the widely adopted compilation of reaction rates (NACRE or CF88) and the uncertainty is now reduced down to the 10% level.
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Submitted 22 July, 2011;
originally announced July 2011.
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The 14N(p,gamma)15O reaction studied with a composite germanium detector
Authors:
M. Marta,
A. Formicola,
D. Bemmerer,
C. Broggini,
A. Caciolli,
P. Corvisiero,
H. Costantini,
Z. Elekes,
Zs. Fulop,
G. Gervino,
A. Guglielmetti,
C. Gustavino,
Gy. Gyurky,
G. Imbriani,
M. Junker,
A. Lemut,
B. Limata,
C. Mazzocchi,
R. Menegazzo,
P. Prati,
V. Roca,
C. Rolfs,
C. Rossi Alvarez,
E. Somorjai,
O. Straniero
, et al. (4 additional authors not shown)
Abstract:
The rate of the carbon-nitrogen-oxygen (CNO) cycle of hydrogen burning is controlled by the 14N(p,gamma)15O reaction. The reaction proceeds by capture to the ground states and several excited states in O-15. In order to obtain a reliable extrapolation of the excitation curve to astrophysical energy, fits in the R-matrix framework are needed. In an energy range that sensitively tests such fits, new…
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The rate of the carbon-nitrogen-oxygen (CNO) cycle of hydrogen burning is controlled by the 14N(p,gamma)15O reaction. The reaction proceeds by capture to the ground states and several excited states in O-15. In order to obtain a reliable extrapolation of the excitation curve to astrophysical energy, fits in the R-matrix framework are needed. In an energy range that sensitively tests such fits, new cross section data are reported here for the four major transitions in the 14N(p,gamma)15O reaction. The experiment has been performed at the Laboratory for Underground Nuclear Astrophysics (LUNA) 400 kV accelerator placed deep underground in the Gran Sasso facility in Italy. Using a composite germanium detector, summing corrections have been considerably reduced with respect to previous studies. The cross sections for capture to the ground state and to the 5181, 6172, and 6792 keV excited states in O-15 have been determined at 359, 380, and 399 keV beam energy. In addition, the branching ratios for the decay of the 278 keV resonance have been remeasured.
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Submitted 28 March, 2011;
originally announced March 2011.