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1. Relativistic Atomic Structure of Au IV and the Os Isoelectronic Sequence: Opacity Data for Kilonova Ejecta

   https://doi.org/10.3390/atoms10030094  

   Taghadomi, Zahra Sadat; Wan, Yier; Flowers, Alicia; Stancil, Phillip; McLaughlin, Brendan; Bromley, Steven; Marler, Joan; Sosolik, Chad; Loch, Stuart (September 2022, Atoms)

   Direct detection of gravitational waves (GWs) on 17 August 2017, propagating from a binary neutron star merger, or a “kilonova”, opened the era of multimessenger astronomy. The ejected material from neutron star mergers, or “kilonova”, is a good candidate for optical and near infrared follow-up observations after the detection of GWs. The kilonova from the ejecta of GW1780817 provided the first evidence for the astrophysical site of the synthesis of heavy nuclei through the rapid neutron capture process or r-process. Since properties of the emission are largely affected by opacities of the ejected material, enhancements in the available r-process data is important for neutron star merger modeling. However, given the complexity of the electronic structure of these heavy elements, considerable efforts are still needed to converge to a reliable set of atomic structure data. The aim of this work is to alleviate this situation for low charge state elements in the Os-like isoelectronic sequence. In this regard, the general-purpose relativistic atomic structure packages (GRASP0 and GRASP2K) were used to obtain energy levels and transition probabilities (E1 and M1). We provide line lists and expansion opacities for a range of r-process elements. We focus here on the Os isoelectronic sequence (Os I, Ir II, Pt III, Au IV, Hg V). The results are benchmarked against existing experimental data and prior calculations, and predictions of emission spectra relevant to kilonovae are provided. Fine-structure (M1) lines in the infrared potentially observable by the James Webb Space Telescope are highlighted. 

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2. WINTER on S250206dm: A Near-infrared Search for an Electromagnetic Counterpart to a Gravitational-wave Event

   https://doi.org/10.1088/1538-3873/ade478  

   Frostig, Danielle; Karambelkar, Viraj R; Stein, Robert D; Lourie, Nathan P; Kasliwal, Mansi M; Simcoe, Robert A; Bulla, Mattia; Ahumada, Tomás; Mo, Geoffrey; Purdum, Josiah; et al (July 2025, Publications of the Astronomical Society of the Pacific)

   Abstract We present near-infrared follow-up observations of the International Gravitational Wave Network event S250206dm with the Wide-Field Infrared Transient Explorer (WINTER). Near-infrared observations are a critical component of electromagnetic follow-up to gravitational-wave events, as kilonovae are expected to exhibit long-lived emission at these wavelengths, especially from lanthanide-rich ejecta. WINTER is a near-infrared time-domain survey facility designed for EM follow-up of gravitational-wave sources, featuring a wide field of view (1.2 deg²), a dedicated 1 m robotic telescope, and coverage spanning 0.9–1.7μm. S250206dm is the only neutron star merger in the fourth observing run, to date, localized to ≤300 deg²with a False Alarm Rate below one per year, making it a particularly valuable target for follow-up. It has a 55% probability of being a neutron star-black hole merger and a 37% probability of being a binary neutron star merger. The event’s estimated distance is 373 Mpc, with a 50% credible region spanning 38 deg². WINTER covered 43% of the probability area at least once and 35% at least three times. Through automated and human candidate vetting, all transients were rejected as kilonova candidates. Given the large distance of the event, the WINTER upper limits do not place meaningful constraints on kilonova models. However, similar observations of future events-or in combination with optical surveys-can begin to exclude portions of the kilonova model space. This study highlights the promise of systematic infrared searches and the need for future wider and deeper infrared surveys. 

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3. 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)

   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 underproduce r-process abundances beyond the second r-process peak. For sufficiently long-lived remnants, these outflows alone can produce blue kilonovae, including the blue kilonova component observed for AT2017gfo. 

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4. Secular Outflows from Long-Lived Neutron Star Merger Remnants

   https://doi.org/10.1088/1742-6596/2742/1/012009  

   Radice, David; Bernuzzi, Sebastiano (April 2024, Journal of Physics: Conference Series)

   Abstract We study mass ejection from a binary neutron star merger producing a long-lived massive neutron star remnant with general-relativistic neutrino-radiation hydrodynamics simulations. In addition to outflows generated by shocks and tidal torques during and shortly after the merger, we observe the appearance of a wind driven by spiral density waves in the disk. This spiral-wave-driven outflow is predominantly located close to the disk orbital plane and have a broad distribution of electron fractions. At higher latitudes, a high electron-fraction wind is driven by neutrino radiation. The combined nucleosynthesis yields from all the ejecta components is in good agreement with Solar abundance measurements. 

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5. A Short Gamma-Ray Burst from a Protomagnetar Remnant

   https://doi.org/10.3847/1538-4357/ac972b  

   Jordana-Mitjans, N.; Mundell, C. G.; Guidorzi, C.; Smith, R. J.; Ramírez-Ruiz, E.; Metzger, B. D.; Kobayashi, S.; Gomboc, A.; Steele, I. A.; Shrestha, M.; et al (November 2022, The Astrophysical Journal)

   Abstract The contemporaneous detection of gravitational waves and gamma rays from GW170817/GRB 170817A, followed by kilonova emission a day after, confirmed compact binary neutron star mergers as progenitors of short-duration gamma-ray bursts (GRBs) and cosmic sources of heavy r -process nuclei. However, the nature (and life span) of the merger remnant and the energy reservoir powering these bright gamma-ray flashes remains debated, while the first minutes after the merger are unexplored at optical wavelengths. Here, we report the earliest discovery of bright thermal optical emission associated with short GRB 180618A with extended gamma-ray emission—with ultraviolet and optical multicolor observations starting as soon as 1.4 minutes post-burst. The spectrum is consistent with a fast-fading afterglow and emerging thermal optical emission 15 minutes post-burst, which fades abruptly and chromatically (flux density F ν ∝ t − α , α = 4.6 ± 0.3) just 35 minutes after the GRB. Our observations from gamma rays to optical wavelengths are consistent with a hot nebula expanding at relativistic speeds, powered by the plasma winds from a newborn, rapidly spinning and highly magnetized neutron star (i.e., a millisecond magnetar), whose rotational energy is released at a rate L th ∝ t −(2.22±0.14) to reheat the unbound merger-remnant material. These results suggest that such neutron stars can survive the collapse to a black hole on timescales much larger than a few hundred milliseconds after the merger and power the GRB itself through accretion. Bright thermal optical counterparts to binary merger gravitational wave sources may be common in future wide-field fast-cadence sky surveys. 

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