Revisit the fundamental plane of black-hole activity from sub-Eddington to quiescent state

Abstract

It is very controversial whether radio--X-ray correlation as defined in LH state of XRBs can extend to quiescent state (e.g., X-ray luminosity less than a critical value of L X,c 10-5.5L Edd) or not. In this work, we collect a sample of XRBs and low luminosity active galactic nuclei (LLAGNs) with wide distribution of Eddington ratios to reexplore the fundamental plane between 5 GHz radio luminosity, L R, 2-10 keV X-ray luminosity, L X, and black hole (BH) mass, M BH, namely L R= X L X+ M M BH+ constant. For the whole sample, we confirm the former fundamental plane of Merloni et al. and Falcke et al. that X 0.6 and M 0.8 even after including more quiescent BHs. The quiescent BHs follow the fundamental plane very well, and, however, FR I radio galaxies follow a steeper track comparing other BH sources. After excluding FR Is, we investigate the fundamental plane for BHs in quiescent state with L X< L X,c and sub-Eddington BHs with L X> L X,c respectively, and both subsamples have a similar slope, X0.6, which support that quiescent BHs may behave similar to those in low-hard state. We further select two subsamples of AGNs with BH mass in a narrow range (FR Is with M BH=108.80.4 and other LLAGNs with M BH=108.00.4) to simulate the behavior of a single supermassive BH evolving from sub-Eddington to quiescent state. We find that the highly sub-Eddington sources with L X/L Edd10-6-10-9 still roughly stay on the extension of radio--X-ray correlation as defined by other sub-Eddington BHs. Our results are consistent with several recent observations in XRBs that the radio--X-ray correlation as defined in low-hard state can extend to highly sub-Eddington quiescent state.