R-process nucleosynthesis: Connecting rare-isotope beam facilities with the cosmos

C. J. Horowitz; A. Arcones; B. Côté; I. Dillmann; W. Nazarewicz; I. U. Roederer; H. Schatz; A. Aprahamian; D. Atanasov; A. Bauswein; T. C. Beers; J. Bliss; M. Brodeur; J. A. Clark; A. Frebel; F. Foucart; C. J. Hansen; O. Just; A. Kankainen; G. C. McLaughlin; J. M. Kelly; S. N. Liddick; D. M. Lee; J. Lippuner; D. Martin; J. Mendoza-Temis; B. D. Metzger; M. R. Mumpower; G. Perdikakis; J. Pereira; B. W. O'Shea; R. Reifarth; A. M. Rogers; D. M. Siegel; A. Spyrou; R. Surman; X. Tang; T. Uesaka; M. Wang

doi:10.1088/1361-6471/ab0849

R-process nucleosynthesis: Connecting rare-isotope beam facilities with the cosmos

C. J. Horowitz, A. Arcones, B. Côté, I. Dillmann, W. Nazarewicz, I. U. Roederer, H. Schatz, A. Aprahamian, D. Atanasov, A. Bauswein, T. C. Beers, J. Bliss, M. Brodeur, J. A. Clark, A. Frebel, F. Foucart, C. J. Hansen, O. Just, A. Kankainen, G. C. McLaughlinJ. M. Kelly, S. N. Liddick, D. M. Lee, J. Lippuner, D. Martin, J. Mendoza-Temis, B. D. Metzger, M. R. Mumpower, G. Perdikakis, J. Pereira, B. W. O'Shea, R. Reifarth, A. M. Rogers, D. M. Siegel, A. Spyrou, R. Surman, X. Tang, T. Uesaka, M. Wang

Physics

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Abstract

This is an exciting time for the study of r-process nucleosynthesis. Recently, a neutron star merger GW170817 was observed in extraordinary detail with gravitational waves and electromagnetic radiation from radio to γ rays. The very red color of the associated kilonova suggests that neutron star mergers are an important r-process site. Astrophysical simulations of neutron star mergers and core collapse supernovae are making rapid progress. Detection of both electron neutrinos and antineutrinos from the next galactic supernova will constrain the composition of neutrino-driven winds and provide unique nucleosynthesis information. Finally, FRIB and other rare-isotope beam facilities will soon have dramatic new capabilities to synthesize many neutron-rich nuclei that are involved in the r-process. The new capabilities can significantly improve our understanding of the r-process and likely resolve one of the main outstanding problems in classical nuclear astrophysics. However, to make best use of the new experimental capabilities and to fully interpret the results, a great deal of infrastructure is needed in many related areas of astronomy, astrophysics, and nuclear theory. We place these experiments in context by discussing astrophysical simulations and observations of r-process sites, observations of stellar abundances, galactic chemical evolution, and nuclear theory for the structure and reactions of very neutron-rich nuclei. This review paper was initiated at a three-week International Collaborations in Nuclear Theory program in June 2016, where we explored promising r-process experiments and discussed their likely impact, and their astronomical, astrophysical, and nuclear theory context.

Original language	English
Article number	083001
Journal	Journal of Physics G: Nuclear and Particle Physics
Volume	46
Issue number	8
DOIs	https://doi.org/10.1088/1361-6471/ab0849
State	Published - Jul 12 2019

Keywords

galactic chemical evolution
nucleosynthesis
r-process nucleosynthesis
rare-isotope beam facilities

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10.1088/1361-6471/ab0849

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Horowitz, C. J., Arcones, A., Côté, B., Dillmann, I., Nazarewicz, W., Roederer, I. U., Schatz, H., Aprahamian, A., Atanasov, D., Bauswein, A., Beers, T. C., Bliss, J., Brodeur, M., Clark, J. A., Frebel, A., Foucart, F., Hansen, C. J., Just, O., Kankainen, A., ... Wang, M. (2019). R-process nucleosynthesis: Connecting rare-isotope beam facilities with the cosmos. Journal of Physics G: Nuclear and Particle Physics, 46(8), [083001]. https://doi.org/10.1088/1361-6471/ab0849

@article{9452599490a544dbbdaf32a4cf412003,

title = "R-process nucleosynthesis: Connecting rare-isotope beam facilities with the cosmos",

abstract = "This is an exciting time for the study of r-process nucleosynthesis. Recently, a neutron star merger GW170817 was observed in extraordinary detail with gravitational waves and electromagnetic radiation from radio to γ rays. The very red color of the associated kilonova suggests that neutron star mergers are an important r-process site. Astrophysical simulations of neutron star mergers and core collapse supernovae are making rapid progress. Detection of both electron neutrinos and antineutrinos from the next galactic supernova will constrain the composition of neutrino-driven winds and provide unique nucleosynthesis information. Finally, FRIB and other rare-isotope beam facilities will soon have dramatic new capabilities to synthesize many neutron-rich nuclei that are involved in the r-process. The new capabilities can significantly improve our understanding of the r-process and likely resolve one of the main outstanding problems in classical nuclear astrophysics. However, to make best use of the new experimental capabilities and to fully interpret the results, a great deal of infrastructure is needed in many related areas of astronomy, astrophysics, and nuclear theory. We place these experiments in context by discussing astrophysical simulations and observations of r-process sites, observations of stellar abundances, galactic chemical evolution, and nuclear theory for the structure and reactions of very neutron-rich nuclei. This review paper was initiated at a three-week International Collaborations in Nuclear Theory program in June 2016, where we explored promising r-process experiments and discussed their likely impact, and their astronomical, astrophysical, and nuclear theory context.",

keywords = "galactic chemical evolution, nucleosynthesis, r-process nucleosynthesis, rare-isotope beam facilities",

author = "Horowitz, {C. J.} and A. Arcones and B. C{\^o}t{\'e} and I. Dillmann and W. Nazarewicz and Roederer, {I. U.} and H. Schatz and A. Aprahamian and D. Atanasov and A. Bauswein and Beers, {T. C.} and J. Bliss and M. Brodeur and Clark, {J. A.} and A. Frebel and F. Foucart and Hansen, {C. J.} and O. Just and A. Kankainen and McLaughlin, {G. C.} and Kelly, {J. M.} and Liddick, {S. N.} and Lee, {D. M.} and J. Lippuner and D. Martin and J. Mendoza-Temis and Metzger, {B. D.} and Mumpower, {M. R.} and G. Perdikakis and J. Pereira and O'Shea, {B. W.} and R. Reifarth and Rogers, {A. M.} and Siegel, {D. M.} and A. Spyrou and R. Surman and X. Tang and T. Uesaka and M. Wang",

note = "Funding Information: This research was enabled by a workshop jointly organized by the Joint Institute for Nuclear Astrophysics Center for the Evolution of the Elements (JINA-CEE), supported by the National Science Foundation under grant no. PHY-1430152, and the International Collaborations in Nuclear Theory program. TCB and IUR acknowledge partial support for this work from grant PHY 14-30152; Physics Frontier Center/JINA Center for the Evolution of the Elements (JINA-CEE), awarded by the US National Science Foundation. WN is supported by the US Department of Energy under Award Numbers DOE-DENA0002847 (the Stewardship Science Academic Alliances program), DE-SC0018083 (NUCLEI SciDAC-4 collaboration), and DE-SC0013365 (Michigan State University); CH is supported by the US Department of Energy under Award Numbers DOE-DE-FG02- 87ER40365 (Indiana University) and DE-SC0018083 (NUCLEI SciDAC-4 collaboration); HS is supported by the US National Science Foundation under grant no. PHY-1102511; AA was supported by the Helmholtz-University Young Investigator grant No. VH-NG-825, Deutsche Forschungsgemeinschaft through SFB 1245, and European Research Council through ERC Starting Grant No. 677912 EUROPIUM ID is supported by the Canadian NSERC Discovery Grants SAPIN-2014-00028 and RGPAS 462257-2014. DA acknowledges support by the IMPRS-PTFS. JM-T is supported by a Mexican grant under the project UNAM-DGAPA/PAPIIT IV100116. RR is supported by the European Research Council under the European Unionsas Seventh Framework Programme (FP/2007-2013) / ERC Grant Agreement n. 615126. Publisher Copyright: {\textcopyright} 2019 IOP Publishing Ltd.",

year = "2019",

month = jul,

day = "12",

doi = "10.1088/1361-6471/ab0849",

language = "English",

volume = "46",

journal = "Journal of Physics G: Nuclear and Particle Physics",

issn = "0954-3899",

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Horowitz, CJ, Arcones, A, Côté, B, Dillmann, I, Nazarewicz, W, Roederer, IU, Schatz, H, Aprahamian, A, Atanasov, D, Bauswein, A, Beers, TC, Bliss, J, Brodeur, M, Clark, JA, Frebel, A, Foucart, F, Hansen, CJ, Just, O, Kankainen, A, McLaughlin, GC, Kelly, JM, Liddick, SN, Lee, DM, Lippuner, J, Martin, D, Mendoza-Temis, J, Metzger, BD, Mumpower, MR, Perdikakis, G, Pereira, J, O'Shea, BW, Reifarth, R, Rogers, AM, Siegel, DM, Spyrou, A, Surman, R, Tang, X, Uesaka, T & Wang, M 2019, 'R-process nucleosynthesis: Connecting rare-isotope beam facilities with the cosmos', Journal of Physics G: Nuclear and Particle Physics, vol. 46, no. 8, 083001. https://doi.org/10.1088/1361-6471/ab0849

TY - JOUR

T1 - R-process nucleosynthesis

T2 - Connecting rare-isotope beam facilities with the cosmos

AU - Horowitz, C. J.

AU - Arcones, A.

AU - Côté, B.

AU - Dillmann, I.

AU - Nazarewicz, W.

AU - Roederer, I. U.

AU - Schatz, H.

AU - Aprahamian, A.

AU - Atanasov, D.

AU - Bauswein, A.

AU - Beers, T. C.

AU - Bliss, J.

AU - Brodeur, M.

AU - Clark, J. A.

AU - Frebel, A.

AU - Foucart, F.

AU - Hansen, C. J.

AU - Just, O.

AU - Kankainen, A.

AU - McLaughlin, G. C.

AU - Kelly, J. M.

AU - Liddick, S. N.

AU - Lee, D. M.

AU - Lippuner, J.

AU - Martin, D.

AU - Mendoza-Temis, J.

AU - Metzger, B. D.

AU - Mumpower, M. R.

AU - Perdikakis, G.

AU - Pereira, J.

AU - O'Shea, B. W.

AU - Reifarth, R.

AU - Rogers, A. M.

AU - Siegel, D. M.

AU - Spyrou, A.

AU - Surman, R.

AU - Tang, X.

AU - Uesaka, T.

AU - Wang, M.

N1 - Funding Information: This research was enabled by a workshop jointly organized by the Joint Institute for Nuclear Astrophysics Center for the Evolution of the Elements (JINA-CEE), supported by the National Science Foundation under grant no. PHY-1430152, and the International Collaborations in Nuclear Theory program. TCB and IUR acknowledge partial support for this work from grant PHY 14-30152; Physics Frontier Center/JINA Center for the Evolution of the Elements (JINA-CEE), awarded by the US National Science Foundation. WN is supported by the US Department of Energy under Award Numbers DOE-DENA0002847 (the Stewardship Science Academic Alliances program), DE-SC0018083 (NUCLEI SciDAC-4 collaboration), and DE-SC0013365 (Michigan State University); CH is supported by the US Department of Energy under Award Numbers DOE-DE-FG02- 87ER40365 (Indiana University) and DE-SC0018083 (NUCLEI SciDAC-4 collaboration); HS is supported by the US National Science Foundation under grant no. PHY-1102511; AA was supported by the Helmholtz-University Young Investigator grant No. VH-NG-825, Deutsche Forschungsgemeinschaft through SFB 1245, and European Research Council through ERC Starting Grant No. 677912 EUROPIUM ID is supported by the Canadian NSERC Discovery Grants SAPIN-2014-00028 and RGPAS 462257-2014. DA acknowledges support by the IMPRS-PTFS. JM-T is supported by a Mexican grant under the project UNAM-DGAPA/PAPIIT IV100116. RR is supported by the European Research Council under the European Unionsas Seventh Framework Programme (FP/2007-2013) / ERC Grant Agreement n. 615126. Publisher Copyright: © 2019 IOP Publishing Ltd.

PY - 2019/7/12

Y1 - 2019/7/12

N2 - This is an exciting time for the study of r-process nucleosynthesis. Recently, a neutron star merger GW170817 was observed in extraordinary detail with gravitational waves and electromagnetic radiation from radio to γ rays. The very red color of the associated kilonova suggests that neutron star mergers are an important r-process site. Astrophysical simulations of neutron star mergers and core collapse supernovae are making rapid progress. Detection of both electron neutrinos and antineutrinos from the next galactic supernova will constrain the composition of neutrino-driven winds and provide unique nucleosynthesis information. Finally, FRIB and other rare-isotope beam facilities will soon have dramatic new capabilities to synthesize many neutron-rich nuclei that are involved in the r-process. The new capabilities can significantly improve our understanding of the r-process and likely resolve one of the main outstanding problems in classical nuclear astrophysics. However, to make best use of the new experimental capabilities and to fully interpret the results, a great deal of infrastructure is needed in many related areas of astronomy, astrophysics, and nuclear theory. We place these experiments in context by discussing astrophysical simulations and observations of r-process sites, observations of stellar abundances, galactic chemical evolution, and nuclear theory for the structure and reactions of very neutron-rich nuclei. This review paper was initiated at a three-week International Collaborations in Nuclear Theory program in June 2016, where we explored promising r-process experiments and discussed their likely impact, and their astronomical, astrophysical, and nuclear theory context.

AB - This is an exciting time for the study of r-process nucleosynthesis. Recently, a neutron star merger GW170817 was observed in extraordinary detail with gravitational waves and electromagnetic radiation from radio to γ rays. The very red color of the associated kilonova suggests that neutron star mergers are an important r-process site. Astrophysical simulations of neutron star mergers and core collapse supernovae are making rapid progress. Detection of both electron neutrinos and antineutrinos from the next galactic supernova will constrain the composition of neutrino-driven winds and provide unique nucleosynthesis information. Finally, FRIB and other rare-isotope beam facilities will soon have dramatic new capabilities to synthesize many neutron-rich nuclei that are involved in the r-process. The new capabilities can significantly improve our understanding of the r-process and likely resolve one of the main outstanding problems in classical nuclear astrophysics. However, to make best use of the new experimental capabilities and to fully interpret the results, a great deal of infrastructure is needed in many related areas of astronomy, astrophysics, and nuclear theory. We place these experiments in context by discussing astrophysical simulations and observations of r-process sites, observations of stellar abundances, galactic chemical evolution, and nuclear theory for the structure and reactions of very neutron-rich nuclei. This review paper was initiated at a three-week International Collaborations in Nuclear Theory program in June 2016, where we explored promising r-process experiments and discussed their likely impact, and their astronomical, astrophysical, and nuclear theory context.

KW - galactic chemical evolution

KW - nucleosynthesis

KW - r-process nucleosynthesis

KW - rare-isotope beam facilities

UR - http://www.scopus.com/inward/record.url?scp=85070370822&partnerID=8YFLogxK

U2 - 10.1088/1361-6471/ab0849

DO - 10.1088/1361-6471/ab0849

M3 - Article

AN - SCOPUS:85070370822

SN - 0954-3899

VL - 46

JO - Journal of Physics G: Nuclear and Particle Physics

JF - Journal of Physics G: Nuclear and Particle Physics

IS - 8

M1 - 083001

ER -

R-process nucleosynthesis: Connecting rare-isotope beam facilities with the cosmos

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