Abstract
The presence of supermassive black holes (SMBHs) with masses up to M. similar to 10(9)M(circle dot) at redshifts z similar or equal to 7.5 suggests that their seeds may have started to grow long before the reionization in ambient medium with pristine chemical composition. During their latest 500 Myr episode of growing from z >= 10 to z similar to 7, the black holes shone as luminous as 10(11)-10(12) L-circle dot, with a cumulative spectrum consisting of the intrinsic continuum from the hot accretion disk, nebular hydrogen, and helium spectral lines, and the free-free continuum from the gas of host halos. Here we address the question of whether such a plain spectrum would allow us to trace the evolution of these growing SMBHs. In our calculations we assume that host galaxies have stellar populations with masses smaller than the masses of their central black holes-the so-called obese black hole galaxies. Within this model we show that for a sufficiently high mass of gas in a host galaxy-not smaller than the mass of a growing black hole, the cumulative spectrum in the far-infrared reveals a sharp transition from a quasi-blackbody Rayleigh-Jeans spectrum of the black hole proportional to lambda(-2) to a flat free-free nebular continuum lambda(0.118) on a longer wavelength limit. Once such a transition in the spectrum is resolved, the black hole mass can be inferred as a combination of the observed wavelength at the transition lambda(k) and the corresponding spectral luminosity. The possible observability of this effect in spectra of growing high-z SMBHs and determination of their mass with the upcoming James Webb Space Telescope and the planned space project Spektr-M is briefly discussed.