η Carinae: Particle acceleration and multimessenger aspects

Abstract: Carinae is composed of two very massive stars orbiting each other in 5.5 years. The primary star features the densest known stellar wind, colliding with that expelled by its companion. The wind collision region dissipates energy and accelerates particles up to relativistic energies, producing nonthermal X-ray and -ray emission detected by Beppo-SAX, INTEGRAL, Swift, Suzaku, Agile, Fermi, and H.E.S.S. The orbital variability of the system provides key diagnosis of the physics involved and of the emission mechan… Show more

“…The stars rotate around one another, with the interacting winds accelerating particles and producing γ-ray and X-ray emission which in turn interacts with the intense thermal photon flux. In [4] the authors analyze the available multi-wavelength data (UV, X, γ), to characterize the spectrum and orbital variability. In particular, the role of future observation in the Cherenkov band (by the Cherenkov Telescope Array) is discussed, to clarify the geometry of the system and the physics of the shocks at a high level of detail.…”

Gamma rays: direct observations

“…The stars rotate around one another, with the interacting winds accelerating particles and producing γ-ray and X-ray emission which in turn interacts with the intense thermal photon flux. In [4] the authors analyze the available multi-wavelength data (UV, X, γ), to characterize the spectrum and orbital variability. In particular, the role of future observation in the Cherenkov band (by the Cherenkov Telescope Array) is discussed, to clarify the geometry of the system and the physics of the shocks at a high level of detail.…”

Gamma rays: direct observations

Overview of non-transientγ-ray binaries and prospects for the Cherenkov Telescope Array