Hydrodynamic Simulations of Pre-supernova Outbursts in Red Supergiants: Asphericity and Mass Loss

Leung, Shing-Chi; Fuller, Jim

doi:10.3847/1538-4357/abac5d

Cited by 28 publications

(37 citation statements)

References 65 publications

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“…Similar to our previous work (Leung & Fuller 2020), when we model the envelope dynamics, we treat the duration of energy deposition as a parameter. This allows us to model the resulting interaction-powered light curve as a function of both the wave-energy deposition and its duration, but we note that the two parameters are linked when modeling the inner core evolution of the star, as investigated in Shiode & Quataert (2014) and Wu & Fuller (2021).…”

Section: General Modeling Methodsmentioning

confidence: 99%

“…To explain the origin of the CSM, a number of mechanisms can trigger greatly enhanced mass loss prior to the final stellar explosion, including common-envelope-triggered mass loss (Chevalier 2012;Schrøder et al 2020), pulsation-induced mass loss in pulsational pair-instability SNe (PPISNe; Umeda & Nomoto 2003;Woosley 2017;Marchant et al 2019;Leung et al 2020a;Woosley 2019;Renzo et al 2020a), enhanced stellar wind in super-asymptotic giant branch stars (Jones et al 2013;Moriya et al 2014;Nomoto & Leung 2017;Tolstov et al 2019), and wave-driven mass loss (Quataert & Shiode 2012;Shiode & Quataert 2014;Fuller 2017;Fuller & Ro 2018;Ouchi & Maeda 2019;Leung & Fuller 2020;Kuriyama & Shigeyama 2021).…”

Section: Circumstellar Medium Interaction Mechanismmentioning

confidence: 99%

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Fast Blue Optical Transients Due to Circumstellar Interaction and the Mysterious Supernova SN 2018gep

Leung

Fuller

Nomoto

2021

ApJ

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The discovery of SN 2018gep (ZTF 18abukavn) challenged our understanding of the late-phase evolution of massive stars and their supernovae (SNe). The fast rise in luminosity of this SN (spectroscopically classified as a broad-lined Type Ic SN) indicates that the ejecta interacts with a dense circumstellar medium (CSM), while an additional energy source such as 56 Ni decay is required to explain the late-time light curve. These features hint at the explosion of a massive star with pre-SN mass loss. In this work, we examine the physical origins of rapidly evolving astrophysical transients like SN 2018gep. We investigate the wave-driven mass-loss mechanism and how it depends on model parameters such as progenitor mass and deposition energy, searching for stellar progenitor models that can reproduce the observational data. A model with an ejecta mass ∼2 M e , explosion energy ∼10 52 erg, a CSM of mass ∼0.3 M e and radius ∼1000 R e , and a 56 Ni mass ∼0.3 M e provides a good fit to the bolometric light curve. We also examine how interaction-powered light curves depend more generally on these parameters and how ejecta velocities can help break degeneracies. We find both wave-driven mass loss and mass ejection via pulsational pair instability can plausibly create the dense CSM in SN 2018gep, but we favor the latter possibility.

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Section: General Modeling Methodsmentioning

confidence: 99%

Section: Circumstellar Medium Interaction Mechanismmentioning

confidence: 99%

Fast Blue Optical Transients Due to Circumstellar Interaction and the Mysterious Supernova SN 2018gep

Leung

Fuller

Nomoto

2021

ApJ

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“…The energy injection can also change the near-surface structure of the star (Owocki et al 2019;Kuriyama & Shigeyama 2020;Leung & Fuller 2020) and hence its observable optical appearance (Kuriyama & Shigeyama 2021). Additionally, the circumstellar medium can greatly affect the light curve of the subsequent supernova (Suzuki et al 2019).…”

Section: Dynamical Evolution Of Massive Starsmentioning

confidence: 99%

Wave-driven Mass Loss of Stripped Envelope Massive Stars: Progenitor-dependence, Mass Ejection, and Supernovae

Leung

Fuller

2021

ApJ

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The discovery of rapidly rising and fading supernovae powered by circumstellar interaction has suggested the pre-supernova mass eruption phase as a critical phenomenon in massive star evolution. It is important to understand the mass and radial extent of the circumstellar medium (CSM) from theoretically predicted mass ejection mechanisms. In this work, we study the wave heating process in massive hydrogen-poor stars, running a suite of stellar models in order to predict the wave energy and pre-explosion timescale of surface energy deposition. We survey stellar models with main-sequence progenitor masses from 20–70 M ⊙ and metallicity from 0.002–0.02. Most of these models predict that less than ∼1047 erg is deposited in the envelope, with the majority of the energy deposited in the last week of stellar evolution. This translates to CSM masses less than ∼10−2 M ⊙ that extend to less than ∼1014 cm, too small to greatly impact the light curves or spectra of the subsequent supernovae, except perhaps during the shock breakout phase. However, a few models predict somewhat higher wave energy fluxes, for which we perform hydrodynamical simulations of the mass ejection process. Radiative transfer simulations of the subsequent supernovae predict a bright but brief shock-cooling phase that could be detected in some Type Ib/c supernovae if they are discovered within a couple days of explosion.

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“…This is expected since metal-poor material presents only very few absorption lines and thus is not efficient in transforming part of the radiative energy into bulk kinetic energy (Kudritzki 2002). However, this conclusion can be different in rotating stellar models as we shall see below (Meynet et al 2006;Hirschi 2007;Ekström et al 2008a), and/or if mass loss is triggered through processes that are not or weakly dependant on metallicity, such as some kinds of pulsations or instabilities triggered by internal gravity waves (Smith & Owocki 2006;Van Marle et al 2008;Yoon & Cantiello 2010;Fuller 2017;Fuller & Ro 2018;Leung & Fuller 2020;Wu & Fuller 2021).…”

Section: Pop III Stellar Evolutionmentioning

confidence: 90%

Stellar winds and metal enrichment from fast-rotating Population III stars

Liu,

Sibony,

Meynet

et al. 2021

Preprint

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Stellar winds from fast-rotating Population III (Pop III) stars have long been suspected to make important contributions to early metal enrichment, as features in the nucleosynthesis of such 'spinstars' are consistent with the chemical abundance patterns of some metal-poor stars in the local Universe. Particularly, stellar winds rich in light elements can provide another pathway towards explaining the carbon enhancement in carbon-enhanced metal-poor (CEMP) stars. In this work, we focus on the feedback of Pop III stellar winds combined with supernovae (SNe), and derive the resulting chemical signatures in the enriched medium. We explore a large parameter space of Pop III star formation and feedback with a semi-analytical model. The predicted pattern of carbon and iron abundances of second-generation stars agrees well with observations of CEMP-no stars ([Ba/Fe] < 0) at [Fe/H] −3 and A(C) 7, under the optimistic assumption of significant mass loss by winds. In this scenario, carbon-rich but ironfree second-generation stars can form in systems dominated by enrichment from winds, gaining trace amounts of iron by accretion from the interstellar medium, to become the most iron-poor and carbon-enhanced stars seen in observations ([Fe/H] −4, [C/Fe] 2). Wind feedback from Pop III spinstars deserves more detailed modelling in early cosmic structure formation.

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Hydrodynamic Simulations of Pre-supernova Outbursts in Red Supergiants: Asphericity and Mass Loss

Cited by 28 publications

References 65 publications

Fast Blue Optical Transients Due to Circumstellar Interaction and the Mysterious Supernova SN 2018gep

Fast Blue Optical Transients Due to Circumstellar Interaction and the Mysterious Supernova SN 2018gep

Wave-driven Mass Loss of Stripped Envelope Massive Stars: Progenitor-dependence, Mass Ejection, and Supernovae

Stellar winds and metal enrichment from fast-rotating Population III stars

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