While the radiative flux cannot substantially exceed the Eddington limit, at which the outgoing radiation pressure impedes the inflow of matter, it remains unclear whether the kinetic energy flux is bounded by this same limit.
Here we present the detection of a radio/optical structure, powered by outflows from a non-nuclear black hole.
Its accretion disk properties indicate that this black hole is less than 100 solar masses.
The optical/IR line emission implies an average kinetic power of 3 × 1040 erg s−1, higher than the Eddington luminosity of the black hole.
These results demonstrate kinetic power exceeding the Eddington limit over a sustained period, which implies greater ability to influence the evolution of the black hole’s environment.
http://scim.ag/1fLBHOT
Here we present the detection of a radio/optical structure, powered by outflows from a non-nuclear black hole.
Its accretion disk properties indicate that this black hole is less than 100 solar masses.
The optical/IR line emission implies an average kinetic power of 3 × 1040 erg s−1, higher than the Eddington luminosity of the black hole.
These results demonstrate kinetic power exceeding the Eddington limit over a sustained period, which implies greater ability to influence the evolution of the black hole’s environment.
http://scim.ag/1fLBHOT
