Insights for Early Massive Black Hole Growth from JWST Detection of the [Ne v] λ3427 Emission Line

Abstract: We use the narrow [Ne v] $\lambda$3427 emission line detected in the recently published JWST spectra of two galaxies, at z = 6.9 and 5.6, to study the key properties of the active galactic nuclei (AGN) and the supermassive black holes in their centers. Using a new empirical scaling linking the [Ne v] line emission with AGN accretion-driven (continuum) emission, derived from a highly complete low-redshift AGN sample, we show that the [Ne v] emission in the two z > 5 galaxies implies total (bolometric) AGN luminosities of order L_bol~(4-8)x10^45 erg/s. Assuming that the radiation emitted from these systems is Eddington limited, the (minimal) black hole masses are of order M_BH>10^7 M_sun. Combined with the published stellar masses of the galaxies, estimated from dedicated fitting of their spectral energy distributions, the implied BH-to-stellar mass ratios are of order M_BH/M_host~0.1-1. This is considerably higher than what is found in the local Universe, but is consistent with the general trend seen in some other z > 5 AGN. Given the intrinsic weakness of the [Ne v] line and the nature of the [Ne v]-to-L_bol scaling, any (rare) detection of the [Ne v] $\lambda$3427 line at z > 5 would translate to similarly high AGN luminosities and SMBH masses, thus providing a unique observational path for studying luminous AGN well into the epoch of reionization, including obscured sources.