Hintze Centre for Astrophysical Surveys

Dynamic shocks powered by a wide, relativistic, super-Eddington outflow launched by an accreting neutron star in the mid-20th century

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2026) stag163

Authors:

FJ Cowie, RP Fender, I Heywood, F Carotenuto, JH Matthews, B Reville, L Olivera-Nieto, AJ Cooper, AK Hughes, K Savard, PA Woudt, J van den Eijnden, N Grollimund, P Saikia

Abstract:

Abstract Accreting systems can launch powerful outflows which interact with the surrounding medium. We combine new radio observations of the accreting neutron star X-ray binary (XRB) Circinus X-1 (Cir X-1) with archival radio observations going back 24 years. The ∼3 pc scale wide-angle radio and X-ray emitting caps found around Cir X-1 are identified as synchrotron emitting shocks with significant proper motion and morphological evolution on decade timescales. Proper motion measurements of the shocks reveal they are mildly relativistic and decelerating, with apparent velocity of 0.14c ± 0.03c at a propagation distance of 2 pc. We demonstrate that these shocks are likely powered by a hidden relativistic (≳ 0.3c) wide-angle conical outflow launched in 1972 ± 3, in stark contrast to known structures around other XRBs formed by collimated jets over 1000s of years. The minimum time-averaged power of the outflow required to produce the observed synchrotron emission is ∼0.1LEdd, while the time-averaged power required for the kinetic energy of the shocks is $\sim 40 \left(\frac{n}{10^{-2} \textrm{cm}^{-3}}\right)L_\textrm{Edd}$, where n is the average ambient medium number density. This reveals the outflow powering the shocks is likely significantly super-Eddington. We measure significant linear polarisation up to 52 ± 6% in the shocks demonstrating the presence of an ordered magnetic field of strength ∼200 μG. We show that the shocks are potential PeVatrons, capable of accelerating electrons to ∼0.7 PeV and protons to ∼20 PeV, and we estimate the injection and energetic efficiencies of electron acceleration in the shocks. Finally, we predict that next generation gamma-ray facilities may be able to detect hadronic signatures from the shocks.

Light travel time effects in kilonova models

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 546:2 (2026) stag068

Authors:

F McNeill, SA Sim, CE Collins, LJ Shingles, R Damgaard, A Sneppen, JH Gillanders

Abstract:

ABSTRACT The extremely rapid evolution of kilonovae results in spectra that change on an hourly basis. These spectra are key to understanding the processes occurring within the event, but this rapid evolution is an unfamiliar domain compared to other explosive transient events, such as supernovae. In particular, the most obvious P Cygni feature in the spectra of AT2017gfo – commonly attributed to strontium – possesses an emission component that emerges after, and ultimately outlives, its associated absorption dip. This delay is theorized to arise from reverberation effects, wherein photons emitted earlier in the kilonova’s evolution are scattered before reaching the observer, causing them to be detected at later times. We aim to examine how the finite speed of light – and therefore the light travel time to an observer – contributes to the shape and evolution of spectral features in kilonovae. Using a simple model, and tracking the length of the journey photons undertake to an observer, we are able to test the necessity of accounting for this time delay effect when modelling kilonovae. In periods where the photospheric temperature is rapidly evolving, we show spectra synthesized using a time-independent approach are visually distinct from those where these time delay effects are accounted for. Therefore, in rapidly evolving events such as kilonovae, time dependence must be taken into account.

A HyperFlash and ÉCLAT view of the local environment and energetics of the repeating FRB 20240619D

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2026) stag090

Authors:

OS Ould-Boukattine, AJ Cooper, JWT Hessels, DM Hewitt, SK Ocker, A Moroianu, K Nimmo, MP Snelders, I Cognard, TJ Dijkema, M Fine, MP Gawroński, W Herrmann, J Huang, F Kirsten, Z Pleunis, W Puchalska, S Ranguin, T Telkamp

Abstract:

Abstract Time-variable propagation effects provide a window into the local plasma environments of repeating fast radio burst (FRB) sources. Here we report high-cadence observations of FRB 20240619D, as part of the HyperFlash and ÉCLAT programs. We observed for 500 h and detected 217 bursts, including 10 bursts with high fluence (>25 Jy ms) and implied energy. We track burst-to-burst variations in dispersion measure (DM) and rotation measure (RM), from which we constrain the parallel magnetic field strength in the source’s local environment: 0.27 ± 0.13 mG. Apparent DM variations between sub-bursts in a single bright event are interpreted as coming from plasma lensing or variable emission height. We also identify two distinct scintillation screens along the line of sight, one associated with the Milky Way and the other likely located in the FRB’s host galaxy or local environment. Together, these (time-variable) propagation effects reveal that FRB 20240619D is embedded in a dense, turbulent and highly magnetised plasma. The source’s environment is more dynamic than that measured for many other (repeating) FRB sources, but less extreme compared to several repeaters that are associated with a compact, persistent radio source. FRB 20240619D’s cumulative burst fluence distribution shows a power-law break, with a flat tail at high energies. Along with previous studies, this emphasises a common feature in the burst energy distribution of hyperactive repeaters. Using the break in the burst fluence distribution, we estimate a source redshift of z = 0.042-0.240. We discuss FRB 20240619D’s nature in the context of similar studies of other repeating FRBs.

A Study of Two Type IIb Supernovae: SNe 2008aq and 2019gaf

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2026) stag093

Authors:

Mridweeka Singh, Devendra K Sahu, Raya Dastidar, Rishabh Singh Teja, Anjasha Gangopadhyay, GC Anupama, D Andrew Howell, K Azalee Bostroem, Curtis McCully, Jamison Burke, Arti Joshi, Daichi Hiramatsu, Hyobin Im, Shubham Srivastav, Kuntal Misra

Abstract:

Abstract We present photometric and spectroscopic studies of two core-collapse supernovae (SNe) 2008aq and 2019gaf in the optical wavelengths. Light curve and spectral sequence of both the SNe are similar to those of other Type IIb SNe. The pre-maximum spectrum of SN 2008aq showed prominent H α lines, the He lines started appearing in the near maximum spectrum. The near maximum spectrum of SN 2019gaf shows shallow H α absorption and He lines with almost similar strength. Both the SNe show transition from hydrogen-dominated spectra to helium-dominated spectra within a month after maximum brightness. The velocity evolution of SN 2008aq matches well with those of other well-studied Type IIb SNe, while SN 2019gaf shows higher velocities. Close to maximum light, the H α and He I line velocities of SN 2019gaf are ∼ 2000 km sec−1 and ∼ 4000 km sec−1 higher than other well-studied Type IIb SNe. Semi-analytical modeling indicates SN 2019gaf to be a more energetic explosion with a smaller ejecta mass than SN 2008aq. The zero-age main-sequence (ZAMS) mass of the progenitor estimated using the nebular spectra of SN 2008aq ranges between 13 to 20 M⊙, while for SN 2019gaf, the inferred ZAMS mass is between 13 to 25 M⊙. The [O i] to [Ca ii] lines flux ratio favors a less massive progenitor star in a binary system for both the SNe.

Cosmic rays, gamma rays and neutrinos from discrete black hole X-ray binary ejecta

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) (2026) stag080

Authors:

Nicolas J Bacon, Alex J Cooper, Dimitrios Kantzas, James H Matthews, Rob Fender

Abstract:

Abstract The origin of cosmic rays from outside the Solar system are unknown, as they are deflected by the interstellar magnetic field. Supernova remnants are the main candidate for cosmic rays up to PeV energies but due to lack of evidence, they cannot be concluded as the sources of the most energetic Galactic CRs. We investigate discrete ejecta produced in state transitions of black hole X-ray binary systems as a potential source of cosmic rays, motivated by recent >100 TeV γ-ray detections by LHAASO. Starting from MAXI J1820+070, we examine the multi-wavelength observations and find that efficient particle acceleration may take place (i.e. into a robust power-law), up to ∼2 × 1016μ−1/2 eV, where μ is the ratio of particle energy to magnetic energy. From these calculations, we estimate the global contribution of ejecta to the entire Galactic spectrum to be $\sim 1~{{\ \rm per\ cent}}$, with the cosmic ray contribution rising to $\sim 5~{{\ \rm per\ cent}}$ at PeV energies, assuming roughly equal energy in non-thermal protons, non-thermal electrons and magnetic fields. In addition, we calculate associated γ-ray and neutrino spectra of the MAXI J1820+070 ejecta to investigate new detection methods with CTAO, which provide strong constraints on initial ejecta size of order 107 Schwarzschild radii (10−5 pc) assuming a period of adiabatic expansion.