del Palacio, S.Benaglia, P.De Becker, M.Bosch i Ramon, ValentíRomero, Gustavo E.2022-07-042023-07-0120221323-3580https://hdl.handle.net/2445/187283The recently discovered massive binary system Apep is the most powerful synchrotron emitter among the known Galactic colliding-wind binaries. This makes this particular system of great interest to investigate stellar winds and the non-thermal processes associated with their shocks. This source was detected at various radio bands, and in addition the wind-collision region was resolved by means of very-long baseline interferometric observations. We use a non-thermal emission model for colliding-wind binaries to derive physical properties of this system. The observed morphology in the resolved maps allows us to estimate the system projection angle on the sky to be ψ≈85∘. The observed radio flux densities also allow us to characterise both the intrinsic synchrotron spectrum of the source and its modifications due to free--free absorption in the stellar winds at low frequencies; from this we derive mass-loss rates of the stars of M˙WN≈4×10−5 M⊙ yr−1 and M˙WC≈2.9×10−5 M⊙ yr−1. Finally, the broadband spectral energy distribution is calculated for different combinations of the remaining free parameters, namely the intensity of the magnetic field and the injected power in non-thermal particles. We show that the degeneracy of these two parameters can be solved with observations in the high-energy domain, most likely in the hard X-rays but also possibly in γ-rays under favourable conditions.application/pdfeng(c) Astronomical Society of Australia, 2022EstelsRadiacióRelativitat (Física)StarsRadiationRelativity (Physics)info:eu-repo/semantics/article7219742022-07-04info:eu-repo/semantics/openAccess