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1. Collective Neutrino Oscillations and Heavy-element Nucleosynthesis in Supernovae: Exploring Potential Effects of Many-body Neutrino Correlations

   https://doi.org/10.3847/1538-4357/ad393d  

   Balantekin, A_Baha; Cervia, Michael_J; Patwardhan, Amol_V; Surman, Rebecca; Wang_王夕露, Xilu (May 2024, The Astrophysical Journal)

   Abstract In high-energy astrophysical processes involving compact objects, such as core-collapse supernovae or binary neutron star mergers, neutrinos play an important role in the synthesis of nuclides. Neutrinos in these environments can experience collective flavor oscillations driven by neutrino–neutrino interactions, including coherent forward scattering and incoherent (collisional) effects. Recently, there has been interest in exploring potential novel behaviors in collective oscillations of neutrinos by going beyond the one-particle effective or “mean-field” treatments. Here, we seek to explore implications of collective neutrino oscillations, in the mean-field treatment and beyond, for the nucleosynthesis yields in supernova environments with different astrophysical conditions and neutrino inputs. We find that collective oscillations can impact the operation of theνp-process andr-process nucleosynthesis in supernovae. The potential impact is particularly strong in high-entropy, proton-rich conditions, where we find that neutrino interactions can nudge an initialνp-process neutron-rich, resulting in a unique combination of proton-rich low-mass nuclei as well as neutron-rich high-mass nuclei. We describe this neutrino-induced neutron-capture process as the “νi-process.” In addition, nontrivial quantum correlations among neutrinos, if present significantly, could lead to different nuclide yields compared to the corresponding mean-field oscillation treatments, by virtue of modifying the evolution of the relevant one-body neutrino observables. 

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2. Three-dimensional General-relativistic Simulations of Neutrino-driven Winds from Magnetized Proto–Neutron Stars

   https://doi.org/10.3847/1538-4357/acea83  

   Desai, Dhruv K.; Siegel, Daniel M.; Metzger, Brian D. (September 2023, The Astrophysical Journal)

   Abstract Formed in the aftermath of a core-collapse supernova or neutron star merger, a hot proto–neutron star (PNS) launches an outflow driven by neutrino heating lasting for up to tens of seconds. Though such winds are considered potential sites for the nucleosynthesis of heavy elements via the rapid neutron capture process (r-process), previous work has shown that unmagnetized PNS winds fail to achieve the necessary combination of high entropy and/or short dynamical timescale in the seed nucleus formation region. We present three-dimensional general-relativistic magnetohydrodynamical simulations of PNS winds which include the effects of a dynamically strong (B≳ 10¹⁵G) dipole magnetic field. After initializing the magnetic field, the wind quickly develops a helmet-streamer configuration, characterized by outflows along open polar magnetic field lines and a “closed” zone of trapped plasma at lower latitudes. Neutrino heating within the closed zone causes the thermal pressure of the trapped material to rise in time compared to the polar outflow regions, ultimately leading to the expulsion of this matter from the closed zone on a timescale of ∼60 ms, consistent with the predictions of Thompson. The high entropies of these transient ejecta are still growing at the end of our simulations and are sufficient to enable a successful second-peakr-process in at least a modest ≳1% of the equatorial wind ejecta. 

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3. The impact of r -process heating on the dynamics of neutron star merger accretion disc winds and their electromagnetic radiation

   https://doi.org/10.1093/mnras/stab3583  

   Klion, Hannah; Tchekhovskoy, Alexander; Kasen, Daniel; Kathirgamaraju, Adithan; Quataert, Eliot; Fernández, Rodrigo (December 2021, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Neutron star merger accretion discs can launch neutron-rich winds of >10−2M⊙. This ejecta is a prime site for r-process nucleosynthesis, which will produce a range of radioactive heavy nuclei. The decay of these nuclei releases enough energy to accelerate portions of the wind by ∼0.1c. Here, we investigate the effect of r-process heating on the dynamical evolution of disc winds. We extract the wind from a 3D general relativistic magnetohydrodynamic simulation of a disc from a post-merger system. This is used to create inner boundary conditions for 2D hydrodynamic simulations that continue the original 3D simulation. We perform two such simulations: one that includes the r-process heating, and another one that does not. We follow the hydrodynamic simulations until the winds reach homology (60 s). Using time-dependent multifrequency multidimensional Monte Carlo radiation transport simulations, we then calculate the kilonova light curves from the winds with and without dynamical r-process heating. We find that the r-process heating can substantially alter the velocity distribution of the wind, shifting the mass-weighted median velocity from 0.06c to 0.12c. The inclusion of the dynamical r-process heating makes the light curve brighter and bluer at $$\sim 1\, \mathrm{d}$$ post-merger. However, the high-velocity tail of the ejecta distribution and the early ($$\lesssim 1\, \mathrm{d}$$) light curves are largely unaffected. 

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4. Systematic exploration of heavy element nucleosynthesis in protomagnetar outflows

   https://doi.org/10.1093/mnras/stac896  

   Ekanger, Nick; Bhattacharya, Mukul; Horiuchi, Shunsaku (April 2022, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT We study the nucleosynthesis products in neutrino-driven winds from rapidly rotating, highly magnetized and misaligned protomagnetars using the nuclear reaction network SkyNet. We adopt a semi-analytic parametrized model for the protomagnetar and systematically study the capabilities of its neutrino-driven wind for synthesizing nuclei and eventually producing ultra-high energy cosmic rays (UHECRs). We find that for neutron-rich outflows (Ye < 0.5), synthesis of heavy elements ($$\overline{A}\sim 20-65$$) is possible during the first $$\sim 10\, {\rm s}$$ of the outflow, but these nuclei are subjected to composition-altering photodisintegration during the epoch of particle acceleration at the dissipation radii. However, after the first $$\sim 10\, {\rm s}$$ of the outflow, nucleosynthesis reaches lighter elements ($$\overline{A}\sim 10-50$$) that are not subjected to subsequent photodisintegration. For proton-rich (Ye ≥ 0.5) outflows, synthesis is more limited ($$\overline{A}\sim 4-15$$). These suggest that while protomagnetars typically do not synthesize nuclei heavier than second r-process peak elements, they are intriguing sources of intermediate/heavy mass UHECRs. For all configurations, the most rapidly rotating protomagnetars are more conducive for nucleosynthesis with a weaker dependence on the magnetic field strength. 

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5. Magnetized Outflows from Short-lived Neutron Star Merger Remnants Can Produce a Blue Kilonova

   https://doi.org/10.3847/2041-8213/ad0fe1  

   Curtis, Sanjana; Bosch, Pablo; Mösta, Philipp; Radice, David; Bernuzzi, Sebastiano; Perego, Albino; Haas, Roland; Schnetter, Erik (January 2024, The Astrophysical Journal Letters)

   Abstract We present a 3D general-relativistic magnetohydrodynamic simulation of a short-lived neutron star remnant formed in the aftermath of a binary neutron star merger. The simulation uses an M1 neutrino transport scheme to track neutrino–matter interactions and is well suited to studying the resulting nucleosynthesis and kilonova emission. A magnetized wind is driven from the remnant and ejects neutron-rich material at a quasi-steady-state rate of 0.8 × 10⁻¹M_⊙s⁻¹. We find that the ejecta in our simulations underproducer-process abundances beyond the secondr-process peak. For sufficiently long-lived remnants, these outflowsalonecan produce blue kilonovae, including the blue kilonova component observed for AT2017gfo. 

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