Understanding the origin of the positron annihilation line and the physics of supernova explosions

F. Frontera; E. Virgilli; C. Guidorzi; P. Rosati; R. Diehl; T. Siegert; C. Fryer; L. Amati; N. Auricchio; R. Campana; E. Caroli; F. Fuschino; C. Labanti; M. Orlandini; E. Pian; J. B. Stephen; S. Del Sordo; C. Budtz-Jorgensen; I. Kuvvetli; S. Brandt; R. M.Curado da Silva; P. Laurent; E. Bozzo; P. Mazzali; M. Della Valle

doi:10.1007/s10686-021-09727-7

Understanding the origin of the positron annihilation line and the physics of supernova explosions

F. Frontera^*, E. Virgilli, C. Guidorzi, P. Rosati, R. Diehl, T. Siegert, C. Fryer, L. Amati, N. Auricchio, R. Campana, E. Caroli, F. Fuschino, C. Labanti, M. Orlandini, E. Pian, J. B. Stephen, S. Del Sordo, C. Budtz-Jorgensen, I. Kuvvetli, S. BrandtR. M.Curado da Silva, P. Laurent, E. Bozzo, P. Mazzali, M. Della Valle

^*Corresponding author for this work

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Abstract

Nuclear astrophysics, and particularly nuclear emission line diagnostics from a variety of cosmic sites, has remained one of the least developed fields in experimental astronomy, despite its central role in addressing a number of outstanding questions in modern astrophysics. Radioactive isotopes are co-produced with stable isotopes in the fusion reactions of nucleosynthesis in supernova explosions and other violent events, such as neutron star mergers. The origin of the 511 keV positron annihilation line observed in the direction of the Galactic Center is a 50-year-long mystery. In fact, we still do not understand whether its diffuse large-scale emission is entirely due to a population of discrete sources, which are unresolved with current poor angular resolution instruments at these energies, or whether dark matter annihilation could contribute to it. From the results obtained in the pioneering decades of this experimentally-challenging window, it has become clear that some of the most pressing issues in high-energy astrophysics and astro-particle physics would greatly benefit from significant progress in the observational capabilities in the keV-to-MeV energy band. Current instrumentation is in fact not sensitive enough to detect radioactive and annihilation lines from a wide variety of phenomena in our and nearby galaxies, let alone study the spatial distribution of their emission. In this White Paper (WP), we discuss how unprecedented studies in this field will become possible with a new low-energy gamma-ray space experiment, called ASTENA (Advanced Surveyor of Transient Events and Nuclear Astrophysics), which combines new imaging, spectroscopic and polarization capabilities. In a separate WP (Guidorzi et al. 39), we discuss how the same mission concept will enable new groundbreaking studies of the physics of Gamma–Ray Bursts and other high-energy transient phenomena over the next decades.

Original language	English
Journal	Experimental Astronomy
Volume	51
Pages (from-to)	1175–1202
ISSN	0922-6435
DOIs	https://doi.org/10.1007/s10686-021-09727-7
Publication status	Published - 2021

Keywords

Dark matter from the Galactic Center region
ESA voyage 2050
Nuclear line distribution across supernova remnants
Nucleosynthesis study in novae
Origin of positron annihilation line from Galactic bulge region
Physical origin of the Phillips law
Space mission concept
Type I and core-collapse supernovae
X–/γ–ray telescopes

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Frontera, F., Virgilli, E., Guidorzi, C., Rosati, P., Diehl, R., Siegert, T., Fryer, C., Amati, L., Auricchio, N., Campana, R., Caroli, E., Fuschino, F., Labanti, C., Orlandini, M., Pian, E., Stephen, J. B., Del Sordo, S., Budtz-Jorgensen, C., Kuvvetli, I., ... Valle, M. D. (2021). Understanding the origin of the positron annihilation line and the physics of supernova explosions. Experimental Astronomy, 51, 1175–1202. https://doi.org/10.1007/s10686-021-09727-7

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abstract = "Nuclear astrophysics, and particularly nuclear emission line diagnostics from a variety of cosmic sites, has remained one of the least developed fields in experimental astronomy, despite its central role in addressing a number of outstanding questions in modern astrophysics. Radioactive isotopes are co-produced with stable isotopes in the fusion reactions of nucleosynthesis in supernova explosions and other violent events, such as neutron star mergers. The origin of the 511 keV positron annihilation line observed in the direction of the Galactic Center is a 50-year-long mystery. In fact, we still do not understand whether its diffuse large-scale emission is entirely due to a population of discrete sources, which are unresolved with current poor angular resolution instruments at these energies, or whether dark matter annihilation could contribute to it. From the results obtained in the pioneering decades of this experimentally-challenging window, it has become clear that some of the most pressing issues in high-energy astrophysics and astro-particle physics would greatly benefit from significant progress in the observational capabilities in the keV-to-MeV energy band. Current instrumentation is in fact not sensitive enough to detect radioactive and annihilation lines from a wide variety of phenomena in our and nearby galaxies, let alone study the spatial distribution of their emission. In this White Paper (WP), we discuss how unprecedented studies in this field will become possible with a new low-energy gamma-ray space experiment, called ASTENA (Advanced Surveyor of Transient Events and Nuclear Astrophysics), which combines new imaging, spectroscopic and polarization capabilities. In a separate WP (Guidorzi et al. 39), we discuss how the same mission concept will enable new groundbreaking studies of the physics of Gamma–Ray Bursts and other high-energy transient phenomena over the next decades.",

keywords = "Dark matter from the Galactic Center region, ESA voyage 2050, Nuclear line distribution across supernova remnants, Nucleosynthesis study in novae, Origin of positron annihilation line from Galactic bulge region, Physical origin of the Phillips law, Space mission concept, Type I and core-collapse supernovae, X–/γ–ray telescopes",

author = "F. Frontera and E. Virgilli and C. Guidorzi and P. Rosati and R. Diehl and T. Siegert and C. Fryer and L. Amati and N. Auricchio and R. Campana and E. Caroli and F. Fuschino and C. Labanti and M. Orlandini and E. Pian and Stephen, {J. B.} and {Del Sordo}, S. and C. Budtz-Jorgensen and I. Kuvvetli and S. Brandt and {da Silva}, {R. M.Curado} and P. Laurent and E. Bozzo and P. Mazzali and Valle, {M. Della}",

note = "Publisher Copyright: {\textcopyright} 2021, The Author(s).",

year = "2021",

doi = "10.1007/s10686-021-09727-7",

language = "English",

volume = "51",

pages = "1175–1202",

journal = "Experimental Astronomy",

issn = "0922-6435",

publisher = "Springer Netherlands",

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Frontera, F, Virgilli, E, Guidorzi, C, Rosati, P, Diehl, R, Siegert, T, Fryer, C, Amati, L, Auricchio, N, Campana, R, Caroli, E, Fuschino, F, Labanti, C, Orlandini, M, Pian, E, Stephen, JB, Del Sordo, S, Budtz-Jorgensen, C , Kuvvetli, I , Brandt, S, da Silva, RMC, Laurent, P, Bozzo, E, Mazzali, P & Valle, MD 2021, 'Understanding the origin of the positron annihilation line and the physics of supernova explosions', Experimental Astronomy, vol. 51, pp. 1175–1202. https://doi.org/10.1007/s10686-021-09727-7

TY - JOUR

T1 - Understanding the origin of the positron annihilation line and the physics of supernova explosions

AU - Frontera, F.

AU - Virgilli, E.

AU - Guidorzi, C.

AU - Rosati, P.

AU - Diehl, R.

AU - Siegert, T.

AU - Fryer, C.

AU - Amati, L.

AU - Auricchio, N.

AU - Campana, R.

AU - Caroli, E.

AU - Fuschino, F.

AU - Labanti, C.

AU - Orlandini, M.

AU - Pian, E.

AU - Stephen, J. B.

AU - Del Sordo, S.

AU - Budtz-Jorgensen, C.

AU - Kuvvetli, I.

AU - Brandt, S.

AU - da Silva, R. M.Curado

AU - Laurent, P.

AU - Bozzo, E.

AU - Mazzali, P.

AU - Valle, M. Della

PY - 2021

Y1 - 2021

N2 - Nuclear astrophysics, and particularly nuclear emission line diagnostics from a variety of cosmic sites, has remained one of the least developed fields in experimental astronomy, despite its central role in addressing a number of outstanding questions in modern astrophysics. Radioactive isotopes are co-produced with stable isotopes in the fusion reactions of nucleosynthesis in supernova explosions and other violent events, such as neutron star mergers. The origin of the 511 keV positron annihilation line observed in the direction of the Galactic Center is a 50-year-long mystery. In fact, we still do not understand whether its diffuse large-scale emission is entirely due to a population of discrete sources, which are unresolved with current poor angular resolution instruments at these energies, or whether dark matter annihilation could contribute to it. From the results obtained in the pioneering decades of this experimentally-challenging window, it has become clear that some of the most pressing issues in high-energy astrophysics and astro-particle physics would greatly benefit from significant progress in the observational capabilities in the keV-to-MeV energy band. Current instrumentation is in fact not sensitive enough to detect radioactive and annihilation lines from a wide variety of phenomena in our and nearby galaxies, let alone study the spatial distribution of their emission. In this White Paper (WP), we discuss how unprecedented studies in this field will become possible with a new low-energy gamma-ray space experiment, called ASTENA (Advanced Surveyor of Transient Events and Nuclear Astrophysics), which combines new imaging, spectroscopic and polarization capabilities. In a separate WP (Guidorzi et al. 39), we discuss how the same mission concept will enable new groundbreaking studies of the physics of Gamma–Ray Bursts and other high-energy transient phenomena over the next decades.

AB - Nuclear astrophysics, and particularly nuclear emission line diagnostics from a variety of cosmic sites, has remained one of the least developed fields in experimental astronomy, despite its central role in addressing a number of outstanding questions in modern astrophysics. Radioactive isotopes are co-produced with stable isotopes in the fusion reactions of nucleosynthesis in supernova explosions and other violent events, such as neutron star mergers. The origin of the 511 keV positron annihilation line observed in the direction of the Galactic Center is a 50-year-long mystery. In fact, we still do not understand whether its diffuse large-scale emission is entirely due to a population of discrete sources, which are unresolved with current poor angular resolution instruments at these energies, or whether dark matter annihilation could contribute to it. From the results obtained in the pioneering decades of this experimentally-challenging window, it has become clear that some of the most pressing issues in high-energy astrophysics and astro-particle physics would greatly benefit from significant progress in the observational capabilities in the keV-to-MeV energy band. Current instrumentation is in fact not sensitive enough to detect radioactive and annihilation lines from a wide variety of phenomena in our and nearby galaxies, let alone study the spatial distribution of their emission. In this White Paper (WP), we discuss how unprecedented studies in this field will become possible with a new low-energy gamma-ray space experiment, called ASTENA (Advanced Surveyor of Transient Events and Nuclear Astrophysics), which combines new imaging, spectroscopic and polarization capabilities. In a separate WP (Guidorzi et al. 39), we discuss how the same mission concept will enable new groundbreaking studies of the physics of Gamma–Ray Bursts and other high-energy transient phenomena over the next decades.

KW - Dark matter from the Galactic Center region

KW - ESA voyage 2050

KW - Nuclear line distribution across supernova remnants

KW - Nucleosynthesis study in novae

KW - Origin of positron annihilation line from Galactic bulge region

KW - Physical origin of the Phillips law

KW - Space mission concept

KW - Type I and core-collapse supernovae

KW - X–/γ–ray telescopes

U2 - 10.1007/s10686-021-09727-7

DO - 10.1007/s10686-021-09727-7

M3 - Journal article

AN - SCOPUS:85105151079

SN - 0922-6435

VL - 51

SP - 1175

EP - 1202

JO - Experimental Astronomy

JF - Experimental Astronomy

ER -

Understanding the origin of the positron annihilation line and the physics of supernova explosions

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Keywords

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