A dark jet dominates the power output of the stellar black hole Cygnus X-1

Abstract

Black holes undergoing accretion are thought to emit the bulk of their power in the X-ray band by releasing the gravitational potential energy of the infalling matter¹. At the same time, they are capable of producing highly collimated jets of energy and particles flowing out of the system with relativistic velocities². Here we show that the 10-solar-mass (10M_⊙) black hole in the X-ray binary Cygnus X-1 (refs 3–5) is surrounded by a large-scale ( ∼ 5 pc in diameter) ring-like structure that appears to be inflated by the inner radio jet⁶. We estimate that in order to sustain the observed emission of the ring, the jet of Cygnus X-1 has to carry a kinetic power that can be as high as the bolometric X-ray luminosity of the binary system. This result may imply that low-luminosity stellar-mass black holes as a whole dissipate the bulk of the liberated accretion power in the form of ‘dark’, radiatively inefficient relativistic outflows, rather than locally in the X-ray-emitting inflow.