Unveiling the first black holes with JWST: multi-wavelength spectral predictions

TL;DR

This paper predicts the multi-wavelength signatures of Obese Black hole Galaxies (OBGs), a new high-redshift class, to aid in their detection and distinguish between different black hole seed formation scenarios using JWST.

Contribution

It introduces the concept of OBGs, models their spectral energy output at high redshift, and develops criteria for their identification with JWST observations.

Findings

OBGs outshine their stellar components at high redshift.

Predicted spectral templates enable selection of OBG candidates.

Criteria include specific color-color cuts and X-ray to optical flux ratios.

Abstract

Growing the supermassive black holes (~10^9 Msun) that power the detected luminous, highest redshift quasars (z > 6) from light seeds - the remnants of the first stars - within ~ 1 Gyr of the Big Bang poses a timing challenge for growth models. The formation of massive black hole seeds via direct collapse with initial masses ~ 10^4 - 10^5 Msun alleviates this problem. Physical conditions required to form these massive direct collapse black hole (DCBH) seeds are available in the early universe. These viable DCBH formation sites, satellite halos of star-forming galaxies, merge and acquire a stellar component. These produce a new, transient class of objects at high redshift, Obese Black hole Galaxies (OBGs), where the luminosity produced by accretion onto the black hole outshines the stellar component. Therefore, the OBG stage offers a unique way to discriminate between light and massive initial seeds. We predict the multi-wavelength energy output of OBGs and growing Pop III remnants at a fiducial redshift (z = 9), exploring both standard and slim disk accretion onto the growing central black hole for high and low metallicities of the associated stellar population. With our computed templates, we derive the selection criteria for OBGs, that comprise a pre-selection that eliminates blue sources; followed by color-color cuts ([F_{070W} - F_{220W}] > 0; -0.3 < [F_{200W} - F_{444W}] < 0.3) and when available, a high ratio of X-ray flux to rest-frame optical flux (F_X/F_{444W} >> 1) (Abridged).