Your search keyword '"Imbriani, Gianluca"' showing total 12 results

1. 12C+12C reactions for Nuclear Astrophysics

Author

Morales-Gallegos Lizeth, Aliotta Marialuisa, Best Andreas, Bruno Carlo G., Buompane Rafaelle, Davinson Thomas, De Cesare Mario, Di Leva Antonino, D’Onofrio Antonio, Duarte Jeremias, Gasques Leandro, Gialanella Lucio, Imbriani Gianluca, Porzio Giuseppe, Rapagnani David, Romoli Mauro, and Terrasi Filippo

Subjects

Physics, QC1-999

Abstract

12C fusion reactions are among the most important in stellar evolution since they determine the destiny of massive stars. Over the past fifty years, massive efforts have been done to measure these reactions at low energies. However, existing data present several discrepancies between sets and large uncertainties specially at the lowest energies. Factors such as beam/environmental backgrounds, extremely low cross sections and insufficient knowledge of the reaction mechanism contribute to these problems. Recently, the ERNA collaboration measured the 12C+12C reactions at Ec.m. = 2.51 - 4.36 MeV with energy steps between 10 and 25 keV in the centre of mass. Representing the smallest energy steps to date. In these measurements, beam induced background was minimised and S-factors for the proton and alpha channels were calculated. Results indicate that a possible explanation for the discrepancies between data sets is the wrongly assumed constant branching ratios and isotropical angular distributions. Given the excellent performance of the detectors for low energy measurements, a collaboration with the LUNA group (LNGS) has started. Background measurements underground are being performed and results indicate it could be possible to measure the 12C+12C reactions directly into the Gamow Window.

Published

2023

2. Shades

Author

Rapagnani David, Ananna Chemseddine, Di Leva Antonino, Imbriani Gianluca, Junker Matthias, Pignatari Marco, and Best Andreas

Subjects

Physics, QC1-999

Abstract

Neutron capture reactions are the main contributors to the synthesis of the heavy elements through the s-process. Together with 13C(α, n)16O, which has recently been measured by the LUNA collaboration in an energy region inside the Gamow peak, 22Ne(α, n)25Mg is the other main neutron source in stars. Its cross section is mostly unknown in the relevant stellar energy (450 keV < Ecm < 750 keV), where only upper limits from direct experiments and highly uncertain estimates from indirect sources exist. The ERC project SHADES (UniNa/INFN) aims to provide for the first time direct cross section data in this region and to reduce the uncertainties of higher energy resonance parameters. High sensitivity measurements will be performed with the new LUNA-MV accelerator at the INFN-LNGS laboratory in Italy: the energy sensitivity of the SHADES hybrid neutron detector, together with the low background environment of the LNGS and the high beam current of the new accelerator promises to improve the sensitivity by over 2 orders of magnitude over the state of the art, allowing to finally probe the unexplored low-energy cross section. Here we present an overview of the project and first results on the setup characterization.

Published

2022

3. Direct measurements of the 12C(12C,p)23Na and 12C(12C,α)20Ne reactions at low energies for Nuclear Astrophysics

Author

Morales-Gallegos Lizeth, Aliotta Marialuisa, Best Andreas, Bruno Carlo G., Buompane Raffaele, Davinson Thomas, De Cesare Mario, Di Leva Antonino, D’Onofrio Antonio, Duarte Jeremias G., Gasques Leandro, Gialanella Lucio, Imbriani Gianluca, Porzio Giuseppe, Rapagnani David, Romoli Mauro, and Terrasi Filippo

Subjects

Physics, QC1-999

Abstract

12C+12C reactions are crucial in the evolution of massive stars and explosive scenarios. The measurement of these reactions at astrophysical energies is very challenging due to their extremely small cross sections, and the presence of beam induced background originated by the natural 1,2H contaminants in the C targets. In addition, the many discrepancies between different data sets and the complicated resonant structure of the cross sections make the extrapolation to low energies very uncertain. Recently, we performed a direct measurement of the 12C+12C reactions at the CIRCE Laboratory in Italy. Results from a study on target contamination were used, allowing us to measure cross sections at Ec.m. =2.51 − 4.36 MeV with 10-25 keV energy steps. Two stage ΔE-Erest detectors were used for unambiguous particle identification. Branching ratios of individual particle groups were found to vary significantly with energy and angular distributions were also found to be anisotropic, which could be a potential explanation for the discrepancies observed among different data sets.

Published

2022

4. The SHADES neutron detection array

Author

Ananna Chemseddine, Rapagnani David, Best Andreas, Di Leva Antonino, and Imbriani Gianluca

Subjects

Physics, QC1-999

Abstract

The detection of neutrons in low energy astrophysics poses two main problems: low cross section measurement requires high detection efficiency and ideally, beam-induced and external neutron backgrounds should be identified through an energy sensitive detector. In recent years, capture-gated neutron spectroscopy has found new opportunities to grow through new materials and better availability of modern data acquisition systems. In this work we will present the design, expected capabilities and preliminary characterization of the hybrid neutron detector array SHADES. Its purpose is the first direct measurement of the reaction 22Ne(α, n)25Mg in the Gamow window for s-process nucleosynthesis with LUNA-MV in the deep underground environment of the LNGS.

Published

2022

5. 12C+12C reactions for Nuclear Astrophysics.

Author

Morales-Gallegos, Lizeth, Aliotta, Marialuisa, Best, Andreas, Bruno, Carlo G., Buompane, Rafaelle, Davinson, Thomas, De Cesare, Mario, Di Leva, Antonino, D'Onofrio, Antonio, Duarte, Jeremias, Gasques, Leandro, Gialanella, Lucio, Imbriani, Gianluca, Porzio, Giuseppe, Rapagnani, David, Romoli, Mauro, and Terrasi, Filippo

Subjects

NUCLEAR astrophysics, NUCLEOSYNTHESIS, NUCLEAR reactions, CENTER of mass, NEUTRON capture

Abstract

12C fusion reactions are among the most important in stellar evolution since they determine the destiny of massive stars. Over the past fifty years, massive efforts have been done to measure these reactions at low energies. However, existing data present several discrepancies between sets and large uncertainties specially at the lowest energies. Factors such as beam/environmental backgrounds, extremely low cross sections and insufficient knowledge of the reaction mechanism contribute to these problems. Recently, the ERNA collaboration measured the 12C+12C reactions at Ec.m. = 2.51 - 4.36 MeV with energy steps between 10 and 25 keV in the centre of mass. Representing the smallest energy steps to date. In these measurements, beam induced background was minimised and S-factors for the proton and alpha channels were calculated. Results indicate that a possible explanation for the discrepancies between data sets is the wrongly assumed constant branching ratios and isotropical angular distributions. Given the excellent performance of the detectors for low energy measurements, a collaboration with the LUNA group (LNGS) has started. Background measurements underground are being performed and results indicate it could be possible to measure the 12C+12C reactions directly into the Gamow Window. [ABSTRACT FROM AUTHOR]

Published

2023

6. 23Na(p,γ)24Mg Cross Section Measurements

Author

Boeltzig Axel, Best Andreas, deBoer Richard J., DiLeva Antonino, Imbriani Gianluca, Junker Matthias, and Wiescher Michael

Subjects

Physics, QC1-999

Abstract

As a link between the NeNa and MgAl cycles in stellar burning, the reaction 23Na(p,γ)24Mg is of interest for various astrophysical scenarios, such as AGB stars. A combined effort at the Laboratory for Underground Nuclear Astrophysics (LUNA) and the Nuclear Science Laboratory (NSL) at the University of Notre Dame aims at a cross section determination for the this reaction, to constrain the astrophysical reaction rate by improving the knowledge of the resonance strengths and the non-resonant component. Experiments at LUNA benefit from the underground location at the Gran Sasso National Laboratory which allows for the measurement of resonances at low energies with high sensitivity in a low background environment. Measurements at the University of Notre Dame pursue a determination of the non-resonant cross section at higher energies. We present the two experiments and the status of the data analysis.

Published

2017

7. Shades: 22Ne(α, n)25Mg reaction rate in the Gamow window.

Author

Rapagnani, David, Ananna, Chemseddine, Di Leva, Antonino, Imbriani, Gianluca, Junker, Matthias, Pignatari, Marco, and Best, Andreas

Subjects

NEUTRON capture, NUCLEAR physics, ELECTRON accelerators, ACCELERATOR physicists, LABORATORIES

Abstract

Neutron capture reactions are the main contributors to the synthesis of the heavy elements through the s-process. Together with 13C(α, n)16O, which has recently been measured by the LUNA collaboration in an energy region inside the Gamow peak, 22Ne(α, n)25Mg is the other main neutron source in stars. Its cross section is mostly unknown in the relevant stellar energy (450 keV < Ecm < 750 keV), where only upper limits from direct experiments and highly uncertain estimates from indirect sources exist. The ERC project SHADES (UniNa/INFN) aims to provide for the first time direct cross section data in this region and to reduce the uncertainties of higher energy resonance parameters. High sensitivity measurements will be performed with the new LUNA-MV accelerator at the INFN-LNGS laboratory in Italy: the energy sensitivity of the SHADES hybrid neutron detector, together with the low background environment of the LNGS and the high beam current of the new accelerator promises to improve the sensitivity by over 2 orders of magnitude over the state of the art, allowing to finally probe the unexplored low-energy cross section. Here we present an overview of the project and first results on the setup characterization. [ABSTRACT FROM AUTHOR]

Published

2022

8. Direct measurements of the 12C(12C,p)23Na and 12C(12C,α)20Ne reactions at low energies for Nuclear Astrophysics.

Author

Morales-Gallegos, Lizeth, Aliotta, Marialuisa, Best, Andreas, Bruno, Carlo G., Buompane, Raffaele, Davinson, Thomas, De Cesare, Mario, Di Leva, Antonino, D'Onofrio, Antonio, Duarte, Jeremias G., Gasques, Leandro, Gialanella, Lucio, Imbriani, Gianluca, Porzio, Giuseppe, Rapagnani, David, Romoli, Mauro, and Terrasi, Filippo

Subjects

ASTROPHYSICS, RESONANCE, GRAVITY assist (Astrodynamics), SPECTRAL energy distribution, ANGULAR distribution (Nuclear physics)

Abstract

12C+12C reactions are crucial in the evolution of massive stars and explosive scenarios. The measurement of these reactions at astrophysical energies is very challenging due to their extremely small cross sections, and the presence of beam induced background originated by the natural 1,2H contaminants in the C targets. In addition, the many discrepancies between different data sets and the complicated resonant structure of the cross sections make the extrapolation to low energies very uncertain. Recently, we performed a direct measurement of the 12C+12C reactions at the CIRCE Laboratory in Italy. Results from a study on target contamination were used, allowing us to measure cross sections at Ec.m. =2.51 − 4.36 MeV with 10-25 keV energy steps. Two stage ΔE-Erest detectors were used for unambiguous particle identification. Branching ratios of individual particle groups were found to vary significantly with energy and angular distributions were also found to be anisotropic, which could be a potential explanation for the discrepancies observed among different data sets. [ABSTRACT FROM AUTHOR]

Published

2022

9. 23Na(p,γ)24Mg Cross Section Measurements.

Author

deBoer, Richard J., Wiescher, Michael, Boeltzig, Axel, Best, Andreas, DiLeva, Antonino, Imbriani, Gianluca, and Junker, Matthias

Subjects

NUCLEAR cross sections, SODIUM compounds, MAGNESIUM isotopes, NUCLEAR reactions, ASYMPTOTIC giant branch stars, ASTROPHYSICS

Abstract

As a link between the NeNa and MgAl cycles in stellar burning, the reaction 23Na(p,γ)24Mg is of interest for various astrophysical scenarios, such as AGB stars. A combined effort at the Laboratory for Underground Nuclear Astrophysics (LUNA) and the Nuclear Science Laboratory (NSL) at the University of Notre Dame aims at a cross section determination for the this reaction, to constrain the astrophysical reaction rate by improving the knowledge of the resonance strengths and the non-resonant component. Experiments at LUNA benefit from the underground location at the Gran Sasso National Laboratory which allows for the measurement of resonances at low energies with high sensitivity in a low background environment. Measurements at the University of Notre Dame pursue a determination of the non-resonant cross section at higher energies. We present the two experiments and the status of the data analysis. [ABSTRACT FROM AUTHOR]

Published

2017

10. Shades

Author

Rapagnani, David, Ananna, Chemseddine, Di Leva, Antonino, Imbriani, Gianluca, Junker, Matthias, Pignatari, Marco, and Best, Andreas

11. Direct measurements of the 12C(12C,p)23Na and 12C(12C,α)20Ne reactions at low energies for Nuclear Astrophysics

Author

Lizeth Morales-Gallegos, Marialuisa Aliotta, Andreas Best, Carlo G. Bruno, Raffaele Buompane, Thomas Davinson, Mario De Cesare, Antonino Di Leva, Antonio D’Onofrio, Jeremias G. Duarte, Leandro Gasques, Lucio Gialanella, Gianluca Imbriani, Giuseppe Porzio, David Rapagnani, Mauro Romoli, Filippo Terrasi, W. Liu, Y. Wang, B. Guo, X. Tang and S. Zeng, Liu, W., Morales-Gallegos, Lizeth, Aliotta, Marialuisa, Best, Andrea, Bruno, Carlo G., Buompane, Raffaele, Davinson, Thoma, De Cesare, Mario, Di Leva, Antonino, D’Onofrio, Antonio, Duarte, Jeremias G., Gasques, Leandro, Gialanella, Lucio, Imbriani, Gianluca, Porzio, Giuseppe, Rapagnani, David, Romoli, Mauro, and Terrasi, Filippo

Abstract

12C+12C reactions are crucial in the evolution of massive stars and explosive scenarios. The measurement of these reactions at astrophysical energies is very challenging due to their extremely small cross sections, and the presence of beam induced background originated by the natural 1,2H contaminants in the C targets. In addition, the many discrepancies between different data sets and the complicated resonant structure of the cross sections make the extrapolation to low energies very uncertain. Recently, we performed a direct measurement of the 12C+12C reactions at the CIRCE Laboratory in Italy. Results from a study on target contamination were used, allowing us to measure cross sections at Ec.m. =2.51 − 4.36 MeV with 10-25 keV energy steps. Two stage ΔE-Erest detectors were used for unambiguous particle identification. Branching ratios of individual particle groups were found to vary significantly with energy and angular distributions were also found to be anisotropic, which could be a potential explanation for the discrepancies observed among different data sets.

Published

2022

12. 23Na(p,γ)24Mg Cross Section Measurements

Author

A. Best, Gianluca Imbriani, Richard deBoer, A. Boeltzig, Michael Wiescher, M. Junker, Antonino DiLeva, Boeltzig, Axel, Best, Andrea, Deboer, Richard J., Dileva, Antonino, Imbriani, Gianluca, Junker, Matthia, and Wiescher, Michael

Subjects

Physics, 010308 nuclear & particles physics, QC1-999, Resonance, 01 natural sciences, Nuclear physics, Reaction rate, Physics and Astronomy (all), Cross section (physics), Stars, 0103 physical sciences, Nuclear astrophysics, Nuclear science, 010306 general physics, National laboratory

Abstract

As a link between the NeNa and MgAl cycles in stellar burning, the reaction 23 Na(p,γ )24 Mg is of interest for various astrophysical scenarios, such as AGB stars. A combined effort at the Laboratory for Underground Nuclear Astrophysics (LUNA) and the Nuclear Science Laboratory (NSL) at the University of Notre Dame aims at a cross section determination for the this reaction, to constrain the astrophysical reaction rate by improving the knowledge of the resonance strengths and the non-resonant component. Experiments at LUNA benefit from the underground location at the Gran Sasso National Laboratory which allows for the measurement of resonances at low energies with high sensitivity in a low background environment. Measurements at the University of Notre Dame pursue a determination of the non-resonant cross section at higher energies. We present the two experiments and the status of the data analysis.

Published

2017