Hintze Centre for Astrophysical Surveys

X-Ray and Radio Monitoring of the Neutron Star Low-mass X-Ray Binary 1A 1744-361: Quasiperiodic Oscillations, Transient Ejections, and a Disk Atmosphere

The Astrophysical Journal American Astronomical Society 966:2 (2024) 232

Authors:

Mason Ng, Andrew K Hughes, Jeroen Homan, Jon M Miller, Sean N Pike, Diego Altamirano, Peter Bult, Deepto Chakrabarty, DJK Buisson, Benjamin M Coughenour, Rob Fender, Sebastien Guillot, Tolga Güver, Gaurava K Jaisawal, Amruta D Jaodand, Christian Malacaria, James CA Miller-Jones, Andrea Sanna, Gregory R Sivakoff, Tod E Strohmayer, John A Tomsick, Jakob van den Eijnden

Abstract:

We report on X-ray (NICER/NuSTAR/MAXI/Swift) and radio (MeerKAT) timing and spectroscopic analysis from a 3 month monitoring campaign in 2022 of a high-intensity outburst of the dipping neutron star low-mass X-ray binary 1A 1744−361. The 0.5–6.8 keV NICER X-ray hardness–intensity and color–color diagrams of the observations throughout the outburst suggest that 1A 1744−361 spent most of its outburst in an atoll-state, but we show that the source exhibited Z-state-like properties at the peak of the outburst, similar to a small sample of other atoll-state sources. A timing analysis with NICER data revealed several instances of an ≈8 Hz quasiperiodic oscillation (QPO; fractional rms amplitudes of ∼5%) around the peak of the outburst, the first from this source, which we connect to the normal branch QPOs seen in the Z-state. Our observations of 1A 1744−361 are fully consistent with the idea of the mass accretion rate being the main distinguishing parameter between atoll- and Z-states. Radio monitoring data by MeerKAT suggests that the source was at its radio-brightest during the outburst peak, and that the source transitioned from the “island” spectral state to the “banana” state within ∼3 days of the outburst onset, launching transient jet ejecta. The observations present the strongest evidence for radio flaring, including jet ejecta, during the island-to-banana spectral state transition at low accretion rates (atoll-state). The source also exhibited Fe xxv, Fe xxvi Kα, and Kβ X-ray absorption lines, whose origins likely lie in an accretion disk atmosphere.

ATClean: A Novel Method for Detecting Low-Luminosity Transients and Application to Pre-explosion Counterparts from SN 2023ixf

(2024)

Authors:

S Rest, A Rest, CD Kilpatrick, JE Jencson, S von Coelln, L Strolger, S Smartt, JP Anderson, A Clocchiatti, DA Coulter, L Denneau, S Gomez, A Heinze, R Ridden-Harper, KW Smith, B Stalder, JL Tonry, Q Wang, Y Zenati

Using the motion of S2 to constrain vector clouds around Sgr A*

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 530:4 (2024) 3740-3751

Authors:

A Foschi, R Abuter, K Abd El Dayem, N Aimar, P Amaro Seoane, A Amorim, JP Berger, H Bonnet, G Bourdarot, W Brandner, R Davies, PT de Zeeuw, D Defrère, J Dexter, A Drescher, A Eckart, F Eisenhauer, NM Förster Schreiber, PJV Garcia, R Genzel, S Gillessen, T Gomes, X Haubois, G Heißel, Th Henning, L Jochum, L Jocou, A Kaufer, L Kreidberg, S Lacour, V Lapeyrère, J-B Le Bouquin, P Léna, D Lutz, F Mang, F Millour, T Ott, T Paumard, K Perraut, G Perrin, O Pfuhl, S Rabien, DC Ribeiro, M Sadun Bordoni, S Scheithauer, J Shangguan, T Shimizu, J Stadler, C Straubmeier, E Sturm, M Subroweit, LJ Tacconi, F Vincent, S von Fellenberg, J Woillez

WISDOM Project -- XIX. Figures of merit for supermassive black hole mass measurements using molecular gas and/or megamaser kinematics

(2024)

Authors:

Hengyue Zhang, Martin Bureau, Mark D Smith, Michele Cappellari, Timothy A Davis, Pandora Dominiak, Jacob S Elford, Fu-Heng Liang, Ilaria Ruffa, Thomas G Williams

Extragalactic Magnetism with SOFIA (SALSA Legacy Program). VII. A Tomographic View of Far-infrared and Radio Polarimetric Observations through MHD Simulations of Galaxies

The Astrophysical Journal American Astronomical Society 966:1 (2024) 43

Authors:

Sergio Martin-Alvarez, Enrique Lopez-Rodriguez, Tara Dacunha, Susan E Clark, Alejandro S Borlaff, Rainer Beck, Francisco Rodríguez Montero, Seoyoung L Jung, Julien Devriendt, Adrianne Slyz, Julia Christine Roman-Duval, Evangelia Ntormousi, Mehrnoosh Tahani, Kandaswamy Subramanian, Daniel A Dale, Pamela M Marcum, Konstantinos Tassis, Ignacio del Moral-Castro, Le Ngoc Tram, Matt J Jarvis

Abstract:

The structure of magnetic fields in galaxies remains poorly constrained, despite the importance of magnetism in the evolution of galaxies. Radio synchrotron and far-infrared (FIR) polarization and polarimetric observations are the best methods to measure galactic scale properties of magnetic fields in galaxies beyond the Milky Way. We use synthetic polarimetric observations of a simulated galaxy to identify and quantify the regions, scales, and interstellar medium (ISM) phases probed at FIR and radio wavelengths. Our studied suite of magnetohydrodynamical cosmological zoom-in simulations features high-resolutions (10 pc full-cell size) and multiple magnetization models. Our synthetic observations have a striking resemblance to those of observed galaxies. We find that the total and polarized radio emission extends to approximately double the altitude above the galactic disk (half-intensity disk thickness of h I radio ∼ h PI radio = 0.23 ± 0.03 kpc) relative to the total FIR and polarized emission that are concentrated in the disk midplane (h I FIR ∼ h PI FIR = 0.11 ± 0.01 kpc). Radio emission traces magnetic fields at scales of ≳300 pc, whereas FIR emission probes magnetic fields at the smallest scales of our simulations. These scales are comparable to our spatial resolution and well below the spatial resolution (<300 pc) of existing FIR polarimetric measurements. Finally, we confirm that synchrotron emission traces a combination of the warm neutral and cold neutral gas phases, whereas FIR emission follows the densest gas in the cold neutral phase in the simulation. These results are independent of the ISM magnetic field strength. The complementarity we measure between radio and FIR wavelengths motivates future multiwavelength polarimetric observations to advance our knowledge of extragalactic magnetism.