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1. Mass Transfer in Eccentric Black Hole–Neutron Star Mergers

   https://doi.org/10.3847/1538-4357/ad9b87  

   Zenati, Yossef; Rozner, Mor; Krolik, Julian H; Most, Elias R (January 2025, The Astrophysical Journal)

   Abstract Black hole–neutron star binaries are of interest in many ways: they are intrinsically transient, radiate gravitational waves detectable by LIGO, and may produceγ-ray bursts. Although it has long been assumed that their late-stage orbital evolution is driven entirely by gravitational wave emission, we show here that in certain circumstances, mass transfer from the neutron star onto the black hole can both alter the binary's orbital evolution and significantly reduce the neutron star's mass: when the fraction of its mass transferred per orbit is ≳10⁻², the neutron star's mass diminishes by order unity, leading to mergers in which the neutron star mass is exceptionally small. The mass transfer creates a gas disk around the black holebeforemerger that can be comparable in mass to the debris remaining after merger, i.e., ~0.1M_⊙. These processes are most important when the initial neutron star–black hole mass ratioqis in the range ≈0.2–0.8, the orbital semimajor axis is 40 ≲ a₀/r_g ≲ 300 (r_g ≡ GM_BH/c²), and the eccentricity is large ate₀ ≳ 0.8. Systems of this sort may be generated through the dynamical evolution of a triple system, as well as by other means. 

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2. Mapping the Outcomes of Stellar Evolution in the Disks of Active Galactic Nuclei

   https://doi.org/10.3847/1538-4357/ada896  

   Fabj, Gaia; Dittmann, Alexander J; Cantiello, Matteo; Perna, Rosalba; Samsing, Johan (February 2025, The Astrophysical Journal)

   Abstract The disks of active galactic nuclei (AGNs) are expected to be populated by numerous stars, either formed in the outer regions of the disk via gravitational instability or captured from the nearby nuclear star cluster. Regardless of their formation mechanism, these stars experience altered evolutionary paths, mostly shaped by the accretion of dense disk material. In this study, through the comparison of different timescales, we chart the evolutionary outcomes of these AGN stars as a function of disk radius and across a range of supermassive black hole masses, spanning from 10⁶to 10⁹M_⊙, for two popular AGN disk models. We find that in the outer regions of the disk, stars evolve similarly to those in the interstellar medium, but in the inner and denser regions, accretion quickly turns low-mass stars into massive stars, and their fate depends on just how quickly they accrete. If accretion occurs at a faster rate than nuclear burning, they can reach a quasi-steady “immortal” state. If stars accrete faster than they can thermally adjust, runaway accretion occurs, potentially preventing a quasi-steady state and altering the disk structure. During the AGN lifetime, in the regions of the disk that produce massive stars, supernovae (SNe) and gamma-ray bursts (GRBs) may occur within the disk over a wide range of optical depths and ambient densities. Subsequently, in the final phase of the AGN, as the disk becomes depleted, formerly immortal stars will be unable to replenish their fuel, leading to additional SNe and GRBs. 

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3. Stellar Evolution in the Disks of Active Galactic Nuclei Produces Rapidly Rotating Massive Stars

   https://doi.org/10.3847/1538-4357/abfb67  

   Jermyn, Adam S.; Dittmann, Alexander J.; Cantiello, Matteo; Perna, Rosalba (June 2021, The Astrophysical Journal)

   Abstract Stars can either be formed in or captured by the accretion disks in active galactic nuclei (AGNs). These AGN stars are irradiated and subject to extreme levels of accretion, which can turn even low-mass stars into very massive ones (M> 100M_⊙) whose evolution may result in the formation of massive compact objects (M> 10M_⊙). Here we explore the spins of these AGN stars and the remnants they leave behind. We find that AGN stars rapidly spin up via accretion, eventually reaching near-critical rotation rates. They further maintain near-critical rotation even as they shed their envelopes, become compact, and undergo late stages of burning. This makes them good candidates to produce high-spin massive black holes, such as the ones seen by LIGO-Virgo in GW 190521g, as well as long gamma-ray bursts and the associated chemical pollution of the AGN disk. 

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4. Mass and Metal Flows in Isolated IllustrisTNG Halos

   https://doi.org/10.3847/1538-4357/addf46  

   Morgan, Jacob; Bailin, Jeremy; Anderson, Annelia (September 2025, The Astrophysical Journal)

   Abstract The circumgalactic medium (CGM) is a reservoir of metals and star-forming fuel. Most baryons in the Universe are in the CGM or the intergalactic medium (IGM). The baryon cycle—how mass and metals reach the CGM from the inner regions of the galaxy and how gas from the CGM replenishes star-forming activity in the inner regions—is an essential question in galaxy evolution. In this paper, we study the flow of mass and metals in a stacked sample of 2770 isolated halos from the IllustrisTNG100 cosmological hydrodynamic simulation. The mean gas flow as a function of radius and angle is similar across a large galactic mass range when accounting for different feedback modes. Although both star formation and black holes cause powerful outflows, the flows from star formation are more angularly restricted. Black hole feedback dominates mass flow throughout the halo, while star formation feedback mainly affects the inner region. When scaling by virial radius (R_v), large dynamical changes occur at 0.2R_vfor most halos, suggesting a characteristic size for the inner galaxy. Despite kinetic-mode feedback from black holes being the primary quenching mechanism in IllustrisTNG, a small population of high-mass kinetic-mode disks are able to form stars. 

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5. Fragmentation in Gravitationally Unstable Collapsar Disks and Subsolar Neutron Star Mergers

   https://doi.org/10.3847/2041-8213/ad6990  

   Metzger, Brian_D; Hui, Lam; Cantiello, Matteo (August 2024, The Astrophysical Journal Letters)

   Abstract Although stable neutron stars (NSs) can in principle exist down to massesM_ns≈ 0.1M_⊙, standard models of stellar core-collapse predict a robust lower limitM_ns≳ 1.2M_⊙, roughly commensurate with the Chandrasekhar massM_Chof the progenitor’s iron core (electron fractionY_e≈ 0.5). However, this limit may be circumvented in sufficiently dense neutron-rich environments (Y_e< 0.5) for which $M_{\mathrm{Ch}}\propto Y_e^2$is reduced to ≲1M_⊙. Such physical conditions could arise in the black hole accretion disks formed from the collapse of rapidly rotating stars (“collapsars”), as a result of gravitational instabilities and cooling-induced fragmentation, similar to models for planet formation in protostellar disks. We confirm that the conditions to form subsolar-mass NS (ssNS) may be marginally satisfied in the outer regions of massive neutrino-cooled collapsar disks. If the disk fragments into multiple ssNSs, their subsequent coalescence offers a channel for precipitating subsolar mass LIGO/Virgo gravitational-wave mergers that does not implicate primordial black holes. The model makes several additional predictions: (1) ∼Hz frequency Doppler modulation of the ssNS-merger gravitational-wave signals due to the binary’s orbital motion in the disk; (2) at least one additional gravitational-wave event (coincident within ≲hours), from the coalescence of the ssNS-merger remnant(s) with the central black hole; (3) an associated gamma-ray burst and supernova counterpart, the latter boosted in energy and enriched withr-process elements from the NS merger(s) embedded within the exploding stellar envelope (“kilonovae inside a supernova”). 

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