A universal radio/X-ray correlation in low/hard state black hole binaries

We present a comprehensive study of (quasi-)simultaneous radio:X-ray observations of stellar black hole binaries during the spectrally hard X-ray state, finding evidence for a strong correlation between these two bands over more than three orders of magnitude in X-ray luminosity. The correlation extends from the quiescent regime up to close to the soft state transition, where radio emission starts to decline, sometimes below detectable levels, probably corresponding to the physical disappearance of the jet. The X-ray transient V 404 Cygni is found to display the same functional relationship already reported for GX 339-4 between radio and X-ray flux, namely S_radio \propto S_X **(+0.7). In fact the data for all low/hard state black holes is consistent with a universal relation between the radio and X-ray luminosity of the form L_radio \propto L_X **(+0.7), implying that - as L_X decreases - the jet becomes more radiatively efficient with respect to the X-rays. Under the hypothesis of common physics driving the disc-jet coupling in different sources, the observed spread to the best-fit relation can be interpreted in terms of a distribution in Doppler factors. Monte Carlo simulations show that, assuming little or no X-ray beaming, the measured scatter in radio power is consistent with Lorentz factors < 2 for the outflows in the low/hard state, significantly less relativistic than the jets associated with X-ray transients. When combined radio and X-ray beaming is considered, the range of possible jet bulk velocities significantly broadens, allowing highly relativistic outflows, but implying therefore severe X-ray selection effects.