POSYDON: A General-purpose Population Synthesis Code with Detailed Binary-evolution Simulations

Tassos Fragos; Jeff J. Andrews; Simone S. Bavera; Christopher P. L. Berry; Scott Coughlin; Aaron Dotter; Prabin Giri; Vicky Kalogera; Aggelos Katsaggelos; Konstantinos Kovlakas; Shamal Lalvani; Devina Misra; Philipp M. Srivastava; Ying Qin; Kyle A. Rocha; Jaime Roman-Garza; Juan Gabriel Serra; Petter Stahle; Meng Sun; Xu Teng; Goce Trajcevski; Nam Hai Tran; Zepei Xing; Emmanouil Zapartas; Michael Zevin

doi:10.3847/1538-4365/ac90c1

POSYDON: A General-purpose Population Synthesis Code with Detailed Binary-evolution Simulations

Tassos Fragos^*, Jeff J. Andrews, Simone S. Bavera, Christopher P. L. Berry, Scott Coughlin, Aaron Dotter, Prabin Giri, Vicky Kalogera, Aggelos Katsaggelos, Konstantinos Kovlakas, Shamal Lalvani, Devina Misra, Philipp M. Srivastava, Ying Qin, Kyle A. Rocha, Jaime Roman-Garza, Juan Gabriel Serra, Petter Stahle, Meng Sun, Xu TengGoce Trajcevski, Nam Hai Tran, Zepei Xing, Emmanouil Zapartas, Michael Zevin

^*Corresponding author for this work

DARK

Research output: Contribution to journal › Journal article › Research › peer-review

73 Citations (Scopus)

9 Downloads (Pure)

Abstract

Most massive stars are members of a binary or a higher-order stellar system, where the presence of a binary companion can decisively alter their evolution via binary interactions. Interacting binaries are also important astrophysical laboratories for the study of compact objects. Binary population synthesis studies have been used extensively over the last two decades to interpret observations of compact-object binaries and to decipher the physical processes that lead to their formation. Here, we present POSYDON, a novel, publicly available, binary population synthesis code that incorporates full stellar structure and binary-evolution modeling, using the MESA code, throughout the whole evolution of the binaries. The use of POSYDON enables the self-consistent treatment of physical processes in stellar and binary evolution, including: realistic mass-transfer calculations and assessment of stability, internal angular-momentum transport and tides, stellar core sizes, mass-transfer rates, and orbital periods. This paper describes the detailed methodology and implementation of POSYDON, including the assumed physics of stellar and binary evolution, the extensive grids of detailed single- and binary-star models, the postprocessing, classification, and interpolation methods we developed for use with the grids, and the treatment of evolutionary phases that are not based on precalculated grids. The first version of POSYDON targets binaries with massive primary stars (potential progenitors of neutron stars or black holes) at solar metallicity.

Original language	English
Article number	45
Journal	Astrophysical Journal, Supplement Series
Volume	264
Issue number	2
Number of pages	46
ISSN	0004-637X
DOIs	https://doi.org/10.3847/1538-4365/ac90c1
Publication status	Published - 1 Feb 2023

Keywords

ROTATING MASSIVE STARS
EQUATION-OF-STATE
X-RAY BINARIES
PULSATIONAL PAIR INSTABILITY
ELECTRON-CAPTURE SUPERNOVAE
GRAVITATIONAL-WAVE SOURCES
SECULAR ORBITAL EVOLUTION
COMMON-ENVELOPE EVOLUTION
BLACK-HOLE BINARIES
DOUBLE WHITE-DWARFS

Access to Document

10.3847/1538-4365/ac90c1Licence: CC BY

Fragos_2023_ApJS_264_45Final published version, 10.7 MBLicence: CC BY

Cite this

Fragos, T., Andrews, J. J., Bavera, S. S., Berry, C. P. L., Coughlin, S., Dotter, A., Giri, P., Kalogera, V., Katsaggelos, A., Kovlakas, K., Lalvani, S., Misra, D., Srivastava, P. M., Qin, Y., Rocha, K. A., Roman-Garza, J., Serra, J. G., Stahle, P., Sun, M., ... Zevin, M. (2023). POSYDON: A General-purpose Population Synthesis Code with Detailed Binary-evolution Simulations. Astrophysical Journal, Supplement Series, 264(2), [45]. https://doi.org/10.3847/1538-4365/ac90c1

POSYDON : A General-purpose Population Synthesis Code with Detailed Binary-evolution Simulations. / Fragos, Tassos; Andrews, Jeff J.; Bavera, Simone S.; Berry, Christopher P. L.; Coughlin, Scott; Dotter, Aaron; Giri, Prabin; Kalogera, Vicky; Katsaggelos, Aggelos; Kovlakas, Konstantinos; Lalvani, Shamal; Misra, Devina; Srivastava, Philipp M.; Qin, Ying; Rocha, Kyle A.; Roman-Garza, Jaime; Serra, Juan Gabriel; Stahle, Petter; Sun, Meng; Teng, Xu; Trajcevski, Goce; Tran, Nam Hai; Xing, Zepei; Zapartas, Emmanouil; Zevin, Michael.

In: Astrophysical Journal, Supplement Series, Vol. 264, No. 2, 45, 01.02.2023.

Research output: Contribution to journal › Journal article › Research › peer-review

Fragos, T, Andrews, JJ, Bavera, SS, Berry, CPL, Coughlin, S, Dotter, A, Giri, P, Kalogera, V, Katsaggelos, A, Kovlakas, K, Lalvani, S, Misra, D, Srivastava, PM, Qin, Y, Rocha, KA, Roman-Garza, J, Serra, JG, Stahle, P, Sun, M, Teng, X, Trajcevski, G, Tran, NH, Xing, Z, Zapartas, E & Zevin, M 2023, 'POSYDON: A General-purpose Population Synthesis Code with Detailed Binary-evolution Simulations', Astrophysical Journal, Supplement Series, vol. 264, no. 2, 45. https://doi.org/10.3847/1538-4365/ac90c1

Fragos, Tassos ; Andrews, Jeff J. ; Bavera, Simone S. ; Berry, Christopher P. L. ; Coughlin, Scott ; Dotter, Aaron ; Giri, Prabin ; Kalogera, Vicky ; Katsaggelos, Aggelos ; Kovlakas, Konstantinos ; Lalvani, Shamal ; Misra, Devina ; Srivastava, Philipp M. ; Qin, Ying ; Rocha, Kyle A. ; Roman-Garza, Jaime ; Serra, Juan Gabriel ; Stahle, Petter ; Sun, Meng ; Teng, Xu ; Trajcevski, Goce ; Tran, Nam Hai ; Xing, Zepei ; Zapartas, Emmanouil ; Zevin, Michael. / POSYDON : A General-purpose Population Synthesis Code with Detailed Binary-evolution Simulations. In: Astrophysical Journal, Supplement Series. 2023 ; Vol. 264, No. 2.

@article{2973d5fb0119491e8fcad91b7550fe4a,

title = "POSYDON: A General-purpose Population Synthesis Code with Detailed Binary-evolution Simulations",

abstract = "Most massive stars are members of a binary or a higher-order stellar system, where the presence of a binary companion can decisively alter their evolution via binary interactions. Interacting binaries are also important astrophysical laboratories for the study of compact objects. Binary population synthesis studies have been used extensively over the last two decades to interpret observations of compact-object binaries and to decipher the physical processes that lead to their formation. Here, we present POSYDON, a novel, publicly available, binary population synthesis code that incorporates full stellar structure and binary-evolution modeling, using the MESA code, throughout the whole evolution of the binaries. The use of POSYDON enables the self-consistent treatment of physical processes in stellar and binary evolution, including: realistic mass-transfer calculations and assessment of stability, internal angular-momentum transport and tides, stellar core sizes, mass-transfer rates, and orbital periods. This paper describes the detailed methodology and implementation of POSYDON, including the assumed physics of stellar and binary evolution, the extensive grids of detailed single- and binary-star models, the postprocessing, classification, and interpolation methods we developed for use with the grids, and the treatment of evolutionary phases that are not based on precalculated grids. The first version of POSYDON targets binaries with massive primary stars (potential progenitors of neutron stars or black holes) at solar metallicity.",

keywords = "ROTATING MASSIVE STARS, EQUATION-OF-STATE, X-RAY BINARIES, PULSATIONAL PAIR INSTABILITY, ELECTRON-CAPTURE SUPERNOVAE, GRAVITATIONAL-WAVE SOURCES, SECULAR ORBITAL EVOLUTION, COMMON-ENVELOPE EVOLUTION, BLACK-HOLE BINARIES, DOUBLE WHITE-DWARFS",

author = "Tassos Fragos and Andrews, {Jeff J.} and Bavera, {Simone S.} and Berry, {Christopher P. L.} and Scott Coughlin and Aaron Dotter and Prabin Giri and Vicky Kalogera and Aggelos Katsaggelos and Konstantinos Kovlakas and Shamal Lalvani and Devina Misra and Srivastava, {Philipp M.} and Ying Qin and Rocha, {Kyle A.} and Jaime Roman-Garza and Serra, {Juan Gabriel} and Petter Stahle and Meng Sun and Xu Teng and Goce Trajcevski and Tran, {Nam Hai} and Zepei Xing and Emmanouil Zapartas and Michael Zevin",

year = "2023",

month = feb,

day = "1",

doi = "10.3847/1538-4365/ac90c1",

language = "English",

volume = "264",

journal = "Astrophysical Journal",

issn = "0004-637X",

publisher = "Institute of Physics Publishing, Inc",

number = "2",

}

TY - JOUR

T1 - POSYDON

T2 - A General-purpose Population Synthesis Code with Detailed Binary-evolution Simulations

AU - Fragos, Tassos

AU - Andrews, Jeff J.

AU - Bavera, Simone S.

AU - Berry, Christopher P. L.

AU - Coughlin, Scott

AU - Dotter, Aaron

AU - Giri, Prabin

AU - Kalogera, Vicky

AU - Katsaggelos, Aggelos

AU - Kovlakas, Konstantinos

AU - Lalvani, Shamal

AU - Misra, Devina

AU - Srivastava, Philipp M.

AU - Qin, Ying

AU - Rocha, Kyle A.

AU - Roman-Garza, Jaime

AU - Serra, Juan Gabriel

AU - Stahle, Petter

AU - Sun, Meng

AU - Teng, Xu

AU - Trajcevski, Goce

AU - Tran, Nam Hai

AU - Xing, Zepei

AU - Zapartas, Emmanouil

AU - Zevin, Michael

PY - 2023/2/1

Y1 - 2023/2/1

N2 - Most massive stars are members of a binary or a higher-order stellar system, where the presence of a binary companion can decisively alter their evolution via binary interactions. Interacting binaries are also important astrophysical laboratories for the study of compact objects. Binary population synthesis studies have been used extensively over the last two decades to interpret observations of compact-object binaries and to decipher the physical processes that lead to their formation. Here, we present POSYDON, a novel, publicly available, binary population synthesis code that incorporates full stellar structure and binary-evolution modeling, using the MESA code, throughout the whole evolution of the binaries. The use of POSYDON enables the self-consistent treatment of physical processes in stellar and binary evolution, including: realistic mass-transfer calculations and assessment of stability, internal angular-momentum transport and tides, stellar core sizes, mass-transfer rates, and orbital periods. This paper describes the detailed methodology and implementation of POSYDON, including the assumed physics of stellar and binary evolution, the extensive grids of detailed single- and binary-star models, the postprocessing, classification, and interpolation methods we developed for use with the grids, and the treatment of evolutionary phases that are not based on precalculated grids. The first version of POSYDON targets binaries with massive primary stars (potential progenitors of neutron stars or black holes) at solar metallicity.

AB - Most massive stars are members of a binary or a higher-order stellar system, where the presence of a binary companion can decisively alter their evolution via binary interactions. Interacting binaries are also important astrophysical laboratories for the study of compact objects. Binary population synthesis studies have been used extensively over the last two decades to interpret observations of compact-object binaries and to decipher the physical processes that lead to their formation. Here, we present POSYDON, a novel, publicly available, binary population synthesis code that incorporates full stellar structure and binary-evolution modeling, using the MESA code, throughout the whole evolution of the binaries. The use of POSYDON enables the self-consistent treatment of physical processes in stellar and binary evolution, including: realistic mass-transfer calculations and assessment of stability, internal angular-momentum transport and tides, stellar core sizes, mass-transfer rates, and orbital periods. This paper describes the detailed methodology and implementation of POSYDON, including the assumed physics of stellar and binary evolution, the extensive grids of detailed single- and binary-star models, the postprocessing, classification, and interpolation methods we developed for use with the grids, and the treatment of evolutionary phases that are not based on precalculated grids. The first version of POSYDON targets binaries with massive primary stars (potential progenitors of neutron stars or black holes) at solar metallicity.

KW - ROTATING MASSIVE STARS

KW - EQUATION-OF-STATE

KW - X-RAY BINARIES

KW - PULSATIONAL PAIR INSTABILITY

KW - ELECTRON-CAPTURE SUPERNOVAE

KW - GRAVITATIONAL-WAVE SOURCES

KW - SECULAR ORBITAL EVOLUTION

KW - COMMON-ENVELOPE EVOLUTION

KW - BLACK-HOLE BINARIES

KW - DOUBLE WHITE-DWARFS

U2 - 10.3847/1538-4365/ac90c1

DO - 10.3847/1538-4365/ac90c1

M3 - Journal article

VL - 264

JO - Astrophysical Journal

JF - Astrophysical Journal

SN - 0004-637X

IS - 2

M1 - 45

ER -