Pulsars, transients and relativistic astrophysics

MIGHTEE-H i: possible interactions with the galaxy NGC 895

Monthly Notices of the Royal Astronomical Society Oxford University Press 521:4 (2023) 5177-5190

Authors:

B Namumba, J Román, J Falcón-Barroso, Jh Knapen, R Ianjamasimanana, E Naluminsa, Gig Józsa, M Korsaga, N Maddox, B Frank, S Sikhosana, S Legodi, C Carignan, Aa Ponomareva, T Jarrett, D Lucero, Om Smirnov, Jm Van Der Hulst, Dj Pisano, K Malek, L Marchetti, M Vaccari, M Jarvis, M Baes, M Meyer, Eak Adams, H Chen, J Delhaize, Sha Rajohnson, S Kurapati, I Heywood, L Verdes-Montenegro

Abstract:

The transformation and evolution of a galaxy is strongly influenced by interactions with its environment. Neutral hydrogen (H i) is an excellent way to trace these interactions. Here, we present H i observations of the spiral galaxy NGC 895, which was previously thought to be isolated. High-sensitivity H i observations from the MeerKAT large survey project MIGHTEE reveal possible interaction features, such as extended spiral arms and the two newly discovered H i companions, that drive us to change the narrative that it is an isolated galaxy. We combine these observations with deep optical images from the Hyper Suprime Camera to show an absence of tidal debris between NGC 895 and its companions. We do find an excess of light in the outer parts of the companion galaxy MGTH_J022138.1-052631, which could be an indication of external perturbation and thus possible sign of interactions. Our analysis shows that NGC 895 is an actively star-forming galaxy with a SFR of 1.75 ± 0.09[M⊙/yr], a value typical for high-stellar mass galaxies on the star-forming main sequence. It is reasonable to state that different mechanisms may have contributed to the observed features in NGC 895, and this emphasizes the need to revisit the target with more detailed observations. Our work shows the high potential and synergy of using state-of-the-art data in both H i and optical to reveal a more complete picture of galaxy environments.

Precise Measurements of Self-absorbed Rising Reverse Shock Emission from Gamma-ray Burst 221009A

(2023)

Authors:

Joe S Bright, Lauren Rhodes, Wael Farah, Rob Fender, Alexander J van der Horst, James K Leung, David RA Williams, Gemma E Anderson, Pikky Atri, David R DeBoer, Stefano Giarratana, David A Green, Ian Heywood, Emil Lenc, Tara Murphy, Alexander W Pollak, Pranav H Premnath, Paul F Scott, Sofia Z Sheikh, Andrew Siemion, David J Titterington

Redshift determination of blazars for the Cherenkov Telescope Array

(2023)

Authors:

Eli Kasai, Paolo Goldoni, Santiago Pita, Catherine Boisson, Michael Backes, Garret Cotter, Filippo D'Ammando, Brian van Soelen

Search for the evaporation of primordial black holes with H.E.S.S

(2023)

Authors:

HESS collaboration, :, F Aharonian, F Ait Benkhali, J Aschersleben, M Boettcher, M Backes, V Barbosa Martins, R Batzo, Y Becherini, D Berge, B Bi, C Boisson, J Bolmont, M de Bony de Lavergne, J Borowska, F Bradascio, R Brose, F Brun, B Bruno, T Bulik, C Burger-Scheidlin, S Caro, S Casanova, J Celic, M Cerruti, T Chand, A Chen, O Chibueze, G Cotter, J Damascene Mbarubucyeye, A Djannati-Atai, K Egberts, C van Eldik, J-P Ernenwein, M Fussling, A Fiasson, G Fichet de Clairfontaine, G Fontaine, S Gabici, S Ghafourizadeh, G Giavitto, D Glawion, JF Glicenstein, G Grolleron, M-H Grondin, L Haerer, M Haupt, JA Hinton, W Hofmann, M Holler, D Horns, Zhiqiu Huang, M Jamrozy, F Jankowsky, V Joshi, I Jung-Richardt, E Kasai, K Katarzynski, B Khelifi, S Klepser, W Kluzniak, Nu Komin, K Kosack, D Kostunin, TL Holch, RG Lang, S Le Stum, F Leitl, A Lemiere, J-P Lenain, F Leuschner, T Lohse, A Luashvili, I Lypova, J Mackey, D Malyshev, V Marandon, P Marchegiani, P Marinos, G Marti-Devesa, R Marx, A Mitchell, R Moderski, L Mohrmann, A Montanari, E Moulin, J Muller, K Nakashima, M de Naurois, J Niemiec, P O'Brien, S Ohm, L Olivera-Nieto, E de Ona Wilhelmi, M Ostrowski, G Puehlhofer, S Panny, M Panter, RD Parsons, G Peron, A Priyana Noel, DA Prokhorov, H Prokoph, M Punch, A Quirrenbach, P Reichherzer, O Reimer, F Rieger, G Rowell, B Rudak, H Rueda Ricarte, V Sahakian, H Salzmann, DA Sanchez, A Santangelo, M Sasaki, HM Schutte, U Schwanke, JNS Shapopi, H Sol, A Specovius, S Spencer, L Stawarz, R Steenkamp, S Steinmassl, C Steppa, I Sushch, H Suzuki, T Takahashi, T Tanaka, T Tavernier, C Thorpe-Morgan, N Tsuji, Y Uchiyama, M Vecchi, J Veh, C Venter, J Vink, SJ Wagner, R White, A Wierzcholska, Yu Wun Wong, M Zacharias, D Zargaryan, AA Zdziarski, A Zech, S Zouari, N Zywucka

The origin of optical emission lines in the soft state of X-ray binary outbursts: The case of MAXI J1820+070

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2023)

Authors:

Kii Koljonen, Ks Long, Jh Matthews, C Knigge

Abstract:

<jats:title>Abstract</jats:title> <jats:p>The optical emission line spectra of X-ray binaries (XRBs) are thought to be produced in an irradiated atmosphere, possibly the base of a wind, located above the outer accretion disc. However, the physical nature of – and physical conditions in – the line-forming region remain poorly understood. Here, we test the idea that the optical spectrum is formed in the transition region between the cool, geometrically thin part of the disc near the mid-plane and a hot, vertically extended atmosphere or outflow produced by X-ray irradiation. We first present a VLT X-Shooter spectrum of XRB MAXI J1820+070 in the soft state associated with its 2018 outburst, which displays a rich set of double-peaked hydrogen and helium recombination lines. Aided by ancillary X-ray spectra and reddening estimates, we then model this spectrum with the Monte Carlo radiative transfer code Python, using a simple biconical disc wind model inspired by radiation-hydrodynamic simulations of irradiation-driven outflows from XRB discs. Such a model can qualitatively reproduce the observed features; nearly all of the optical emission arising from the transonic ‘transition region’ near the base of the wind. In this region, characteristic electron densities are on the order of 1012 − 13 cm−3 , in line with the observed flat Balmer decrement (Hα/Hβ ≈ 1.3). We conclude that strong irradiation can naturally give rise to both the optical line-forming layer in XRB discs and an overlying outflow/atmosphere that produces X-ray absorption lines.</jats:p>