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

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

doi:10.3847/1538-4365/ac90c1

Cited by 53 publications

(54 citation statements)

References 254 publications

(321 reference statements)

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“…For our study, we used the POpulation SYnthesis with Detailed binary-evolution simulatiONs code (POSYDON; see Fragos et al 2023, for a detailed description of the code), a new binary population simulation framework that combines the flexibility of parametric binary population synthesis codes with detailed stellar structure and binary evolution models. Crucial to our study, POSYDON enables a physically accurate and self-consistent determination of the stability and mass-transfer rate evolution of mass-transfer phases thanks to extensive precomputed grids of binary-star models (using the Modules for Experiments in Stellar Astrophysics code or MESA code; Paxton et al 2011Paxton et al , 2013Paxton et al , 2015Paxton et al , 2018Paxton et al , 2019.…”

Section: Methods and Physical Assumptionsmentioning

confidence: 99%

“…We assumed independent distributions of the mass ratio and period; however, recent studies show that there might be a dependence of mass ratios on the orbital periods (Moe & Di Stefano 2017). The initial orbital period is drawn from a power law in log-space (Sana et al 2013) with the same limits as the POSYDON grids (Fragos et al 2023) and the initial orbits are taken as circular since the current POSYDON version only follows the mass-transfer phases for circular binaries. The binary fraction assumed is 0.7 (Sana et al 2012).…”

Section: Initial Binary Propertiesmentioning

confidence: 99%

“…Following the Fryer et al (2012) mechanism, f fb = 1.0 for stellar core masses (of the pre-collapse star) greater than 11 M and for masses lower than 11.0 M , f fb < 1.0. Hence, whenever f fb = 1.0, there is no baryonic mass loss considered, while still accounting for neutrino losses (which is capped at 0.5 M Fragos et al 2023). For NSs, when the SN mechanism follows the prescription from Fryer et al (2012), the fall-back fraction for NSs is f fb < 1.0 (however, for NSs from electron-capture SN, f fb = 0).…”

Section: Asymmetric Natal Kick Normalizationmentioning

confidence: 99%

“…For NSs, when the SN mechanism follows the prescription from Fryer et al (2012), the fall-back fraction for NSs is f fb < 1.0 (however, for NSs from electron-capture SN, f fb = 0). When the SN mechanism follows the prescription from Patton & Sukhbold (2020), it is assumed that there is no fallback on the NS ( f fb = 0.0; Fragos et al 2023). (iii) The natal kicks are not normalized for BHs ( f fb = 0, therefore, n = 1).…”

Section: Asymmetric Natal Kick Normalizationmentioning

confidence: 99%

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X-ray luminosity function of high-mass X-ray binaries: Studying the signatures of different physical processes using detailed binary evolution calculations

Misra

Kovlakas

Fragos

et al. 2023

A&A

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Context. Many physical processes taking place during the evolution of binary stellar systems remain poorly understood. The ever-expanding observational sample of X-ray binaries (XRBs) makes them excellent laboratories for constraining binary evolution theory. Such constraints and useful insights can be obtained by studying the effects of various physical assumptions on synthetic X-ray luminosity functions (XLFs) and comparing them with observed XLFs. Aims. In this work we focus on high-mass X-ray binaries (HMXBs) and study the effects on the XLF of various, poorly constrained assumptions regarding physical processes, such as the common-envelope phase, core collapse, and wind-fed accretion. Methods. We used the new binary population synthesis code POSYDON, which employs extensive precomputed grids of detailed stellar structure and binary evolution models, to simulate the entire evolution of binaries. We generated 96 synthetic XRB populations corresponding to different combinations of model assumptions, including different prescriptions for supernova kicks, supernova remnant masses, common-envelope evolution, circularization at the onset of Roche-lobe overflow, and observable wind-fed accretion. Results. The generated HMXB XLFs are feature-rich, deviating from the commonly assumed single power law. We find a break in our synthetic XLF at luminosity ∼1038 erg s−1, similar to observed XLFs. However, we also find a general overabundance of XRBs (up to a factor of ∼10 for certain model parameter combinations) driven primarily by XRBs with black hole accretors. Assumptions about the transient behavior of Be XRBs, asymmetric supernova kicks, and common-envelope physics can significantly affect the shape and normalization of our synthetic XLFs. We find that less well-studied assumptions regarding the circularization of the orbit at the onset of Roche-lobe overflow and criteria for the formation of an X-ray-emitting accretion disk around wind-accreting black holes can also impact our synthetic XLFs and reduce the discrepancy with observations. Conclusions. Our synthetic XLFs do not always agree well with observations, especially at intermediate X-ray luminosities, which is likely due to uncertainties in the adopted physical assumptions. While some model parameters leave distinct imprints on the shape of the synthetic XLFs and can reduce this deviation, others do not have a significant effect overall. Our study reveals the importance of large-scale parameter studies, highlighting the power of XRBs in constraining binary evolution theory.

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Section: Methods and Physical Assumptionsmentioning

confidence: 99%

Section: Initial Binary Propertiesmentioning

confidence: 99%

Section: Asymmetric Natal Kick Normalizationmentioning

confidence: 99%

Section: Asymmetric Natal Kick Normalizationmentioning

confidence: 99%

See 2 more Smart Citations

X-ray luminosity function of high-mass X-ray binaries: Studying the signatures of different physical processes using detailed binary evolution calculations

Misra

Kovlakas

Fragos

et al. 2023

A&A

Self Cite

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“…Therefore, they are known to have systematic effects on their produced binary populations (e.g., Shao & Li 2019;Gallegos-Garcia et al 2021;Marchant et al 2021). Most of the shortcomings associated with these approximations can be well addressed with state-of-the-art population synthesis codes like POSYDON (Fragos et al 2023), which use detailed MESA simulations (Paxton et al 2011) to model the full evolution of binary systems. Currently, such codes only cover a limited range of metallicities, and so cannot yet be used for studies such as ours.…”

Section: Caveats and Future Workmentioning

confidence: 99%

The Missing Link between Black Holes in High-mass X-Ray Binaries and Gravitational-wave Sources: Observational Selection Effects

Liotine

Zevin

Berry

et al. 2023

ApJ

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There are few observed high-mass X-ray binaries (HMXBs) that harbor massive black holes (BHs), and none are likely to result in a binary black hole (BBH) that merges within a Hubble time; however, we know that massive merging BBHs exist from gravitational-wave (GW) observations. We investigate the role that X-ray and GW observational selection effects play in determining the properties of their respective detected binary populations. We find that, as a result of selection effects, detectable HMXBs and detectable BBHs form at different redshifts and metallicities, with detectable HMXBs forming at much lower redshifts and higher metallicities than detectable BBHs. We also find disparities in the mass distributions of these populations, with detectable merging BBH progenitors pulling to higher component masses relative to the full detectable HMXB population. Fewer than 3% of detectable HMXBs host BHs >35M ⊙ in our simulated populations. Furthermore, we find the probability that a detectable HMXB will merge as a BBH system within a Hubble time is ≃0.6%. Thus, it is unsurprising that no currently observed HMXB is predicted to form a merging BBH with high probability.

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Chemical Evolution of the Universe and its Consequences for Gravitational‐Wave Astrophysics

Chruślińska

2022

Annalen der Physik

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We are now routinely detecting gravitational waves (GW) emitted by merging black holes and neutron stars. Those are the afterlives of massive stars that formed all across the Universe -at different cosmic times and with different metallicities (abundances of elements heavier than helium). Birth metallicity plays an important role in the evolution of massive stars. Consequently, the population properties of mergers are sensitive to the metallicity dependent cosmic star formation history (fSFR(Z,z)). In particular, within the isolated formation scenarios (the focus of this paper), a strong low metallicity preference of the formation of mergers involving black holes was found. The origin of this dependence and its consequences are discussed. Most importantly, uncertainty in the fSFR(Z,z) (substantial even at low redshifts, especially at low metallicity) cannot be ignored in the models. This poses a significant challenge for the interpretation of the observed GW source population properties. Possible paths for improvements and the role of future GW detectors are considered. Recent efforts to determine fSFR(Z,z) and the factors that dominate its uncertainty are summarized. Many of those factors are related to the properties of galaxies that are faint and distant and therefore difficult to observe. The fact that they leave imprint on the properties of mergers as a function of cosmic time makes future GW observations a promising (and complementary to electromagnetic observations) tool to study chemical evolution of galaxies.

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

Cited by 53 publications

References 254 publications

X-ray luminosity function of high-mass X-ray binaries: Studying the signatures of different physical processes using detailed binary evolution calculations

X-ray luminosity function of high-mass X-ray binaries: Studying the signatures of different physical processes using detailed binary evolution calculations

The Missing Link between Black Holes in High-mass X-Ray Binaries and Gravitational-wave Sources: Observational Selection Effects

Chemical Evolution of the Universe and its Consequences for Gravitational‐Wave Astrophysics

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