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1. Probing the Stellar Wind of the Wolf–Rayet Star in IC 10 X-1

   https://doi.org/10.3847/1538-4357/acb155  

   Bhattacharya, Sayantan; Laycock, Silas_G_T; Chené, André-Nicolas; Binder, Breanna_A; Christodoulou, Dimitris_M; Roy, Ankur; Sorabella, Nicholas_M; Cappallo, Rigel_C (February 2023, The Astrophysical Journal)

   Abstract IC 10 X-1 is an eclipsing high-mass X-ray binary containing a stellar-mass black hole (BH) and a Wolf–Rayet (WR) donor star with an orbital period ofP= 34.9 hr. This binary belongs to a group of systems that can be the progenitors of gravitational-wave sources; hence understanding the dynamics of systems such as IC 10 X-1 is of paramount importance. The prominent Heii4686 emission line (previously used in mass estimates of the BH) is out of phase with the X-ray eclipse, suggesting that this line originates somewhere in the ionized wind of the WR star or in the accretion disk. We obtained 52 spectra from the GEMINI/GMOS archive, observed between 2001 and 2019. We analyzed the spectra both individually, and after binning them by orbital phase to improve the signal-to-noise ratio. The radial-velocity curve from the stacked data is similar to historical results, indicating the overall parameters of the binary have remained constant. However, the Heiiline profile shows a correlation with the X-ray hardness-ratio values; also, we report a pronounced skewness of the line profile, and the skewness varies with orbital phase. These results support a paradigm wherein the Heiiline tracks structures in the stellar wind that are produced by interactions with the BH’s ionizing radiation and the accretion flow. We compare the observable signatures of two alternative hypotheses proposed in the literature: wind irradiation plus shadowing, and accretion disk hotspot; and we explore how the line-profile variations fit into each of these models. 

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2. X-Ray Binaries in Nearby Dwarf Galaxy IC 10 : Not to Mention the X-1

   Bhattacharya, Sayantan (June 2024, ProQuest LLC, Dissertations and Theses, University of Massachusetts at Lowell)

   This thesis presents a comprehensive investigation into the stellar populations and blue supergiant high-mass X-ray binaries (BSG-HMXBs) in the dwarf star-forming galaxy IC 10. The study is motivated by two primary objectives: firstly, to conduct a detailed analysis of the blue supergiant x-ray binary population in IC 10, and secondly, to explore the properties of IC 10 X-1, the brightest source in the galaxy, which is identified as a high mass x-ray binary containing a Wolf-Rayet and black hole. The dwarf galaxy in Cassiopeia, IC 10, located in “close” proximity of 660 kpc, captivates astronomers with its young stellar population, abundant Wolf-Rayet stars, and the presence of massive stars in general. Leveraging a series of space-based X-ray telescope (Chandra) observations, we have identified 375 X-ray point sources. Correlating our list of x-ray sources with published optical catalogs we found those having an optical counterpart. Applying an optical color-magnitude selection to isolate blue supergiant stars, we find the final list of intriguing blue supergiants in a compact-object(x-ray) binary. The ongoing starburst in IC 10 has given rise to a diverse collection of exotic compact-object binaries, including IC 10 X-1 (a Wolf-Rayet and Blackhole high mass x-ray binary) and IC 10 X-2 (a Blue supergiant fast x-ray transient). We have also used GEMINI/GMOS optical spectroscopy to enable multi-wavelength characterization of these BSG sources. Furthermore, our investigation into IC 10 X-1 reveals surprising findings regarding its X-ray emission and orbital dynamics. Through multi-wavelength analysis combining optical radial velocity (RV) curves and X-ray eclipse lightcurves, we uncover a quarter phase offset between these two observational features. IC 10 X-1 is a blackhole+Wolf-Rayet (BH+WR) high mass X-ray binary with an orbital period of 34.9 hrs. The BH mass is currently unconstrained, as the BH accretion disk irradiates the WR wind and alters the ionization structure of spectral line formation regions near the WR star. This alteration of the WR wind geometry masquerades as the classic binary RV curve. To understand the nature of this complex system, we perform a detailed multi-wavelength study using optical spectroscopy (GEMINI/GMOS), X-ray phase-resolved spectroscopy (Chandra), and x-ray lightcurve analysis (Chandra+Swift+XMM), aiming to elucidate the orbital period derivative and refine our understanding of the system’s binary parameters and physical nature. Blue SG-XRBs include a major class of progenitors of double-degenerate binaries, hence their numbers are an important factor in modeling the rate of gravitational-wave sources. Identifying the nature of individual sources is a slow and difficult process, but ultimately necessary as it paves the way toward a comprehensive census of X-ray binaries (XRBs), enabling meaningful comparisons with other galaxies, for example, the Magellanic Clouds. 

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3. To binary or not to binary: An analysis of WR 71’s polarized line profiles

   Johnson, R.A. (January 2021, Bulletin of the American Astronomical Society)

   null (Ed.)

   Massive Wolf-Rayet (WR) stars in binary systems may produce supernovae capable of emitting long duration gamma ray bursts. Characterizing the structure of the colliding winds in these systems may help constrain the mass loss and transfer properties and help predict their future evolution. I will present new spectropolarimetric data for the possible WR+O binary system WR 71, collected using RSS at the Southern African Large Telescope. WR 71 is a WN6 whose binary status is unknown, but it displays similar spectropolarimetric variations to the known WR+O binary system V444 Cygni. I investigate the orbital and rotational velocity of WR 71's winds by analyzing its polarized emission line profiles as a function of phase, the first analysis of its kind. I compare the line polarization behavior with predictive models of both colliding wind binaries and single stars with co-rotating interaction regions. Describing the wind structure of WR 71 will help determine the rate of mass loss from the system, an important indicator for LGRB progenitors, and shed light on its binary status. 

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4. On the Origin of Spectral Features Observed during Thermonuclear X-Ray Bursts and in the Aftermath Emission of a Long Burst from 4U 1820–30

   https://doi.org/10.3847/1538-4357/adcc24  

   Jaisawal, Gaurava K; Chenevez, Jérôme; Strohmayer, Tod E; Schatz, Hendrik; in_’t_Zand, J_J M; Güver, Tolga; Altamirano, Diego; Arzoumanian, Zaven; Gendreau, Keith C (June 2025, The Astrophysical Journal)

   Abstract We study 15 thermonuclear X-ray bursts from 4U 1820–30 observed with the Neutron Star Interior Composition Explorer (NICER). We find evidence of a narrow emission line at 1.0 keV and three absorption lines at 1.7, 3.0, and 3.75 keV, primarily around the photospheric radius expansion phase of most bursts. The 1.0 keV emission line remains constant, while the absorption features, attributed to wind-ejected species, are stable but show slight energy shifts, likely due to combined effects of Doppler and gravitational redshifts. We also examine with NICER the “aftermath” of a long X-ray burst (a candidate superburst observed by MAXI) on 2021 August 23 and 24. The aftermath emission recovers within half a day from a flux depression. During this recovery phase, we detect two emission lines at 0.7 and 1 keV, along with three absorption lines whose energies decrease to 1.57, 2.64, and 3.64 keV. Given the nature of the helium white dwarf companion, these absorption lines during the aftermath may originate from an accretion flow, but only if the accretion environment is significantly contaminated by nuclear ashes from the superburst. This provides evidence of temporary metal enhancement in the accreted material due to strong wind loss. Moreover, we suggest that the absorption features observed during the short X-ray bursts and in the superburst aftermath share a common origin in heavy nuclear ashes enriched with elements like Si, Ar, Ca, or Ti, either from the burst wind or from an accretion flow contaminated by the burst wind. 

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5. Multiwavelength scrutiny of X-ray sources in dwarf galaxies: ULXs versus AGNs

   https://doi.org/10.1093/mnras/stad002  

   Thygesen, Erica; Plotkin, Richard M.; Soria, Roberto; Reines, Amy E.; Greene, Jenny E.; Anderson, Gemma E.; Baldassare, Vivienne F.; Owens, Milo G.; Urquhart, Ryan T.; Gallo, Elena; et al (January 2023, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Owing to their quiet evolutionary histories, nearby dwarf galaxies (stellar masses $$M_\star \lesssim 3 \times 10^9 \, \mathrm{M}_\odot$$) have the potential to teach us about the mechanism(s) that ‘seeded’ the growth of supermassive black holes, and also how the first stellar mass black holes formed and interacted with their environments. Here, we present high spatial resolution observations of three dwarf galaxies in the X-ray (Chandra), the optical/near-infrared (Hubble Space Telescope), and the radio (Karl G. Jansky Very Large Array). These three galaxies were previously identified as hosting candidate active galactic nuclei on the basis of lower resolution X-ray imaging. With our new observations, we find that X-ray sources in two galaxies (SDSS J121326.01+543631.6 and SDSS J122111.29+173819.1) are off-nuclear and lack corresponding radio emission, implying they are likely luminous X-ray binaries. The third galaxy (Mrk 1434) contains two X-ray sources (each with LX ≈ 1040 erg s−1) separated by 2.8 arcsec, has a low metallicity [12 + log(O/H)  = 7.8], and emits nebular He ii λ4686 line emission. The northern source has spatially coincident point-like radio emission at 9.0 GHz and extended radio emission at 5.5 GHz. We discuss X-ray binary interpretations (where an ultraluminous X-ray source blows a ‘radio bubble’) and active galactic nucleus interpretations (where an $$\approx 4\times 10^5 \, \mathrm{M}_\odot$$ black hole launches a jet). In either case, we find that the He ii emission cannot be photoionized by the X-ray source, unless the source was ≈30–90 times more luminous several hundred years ago. 

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