Beyond the first galaxies primordial black holes shine

Abstract: The presence of nine candidate galaxies at $z=17$ and $z=25$ discovered by the \textit{James Webb Space Telescope} in relatively small sky areas, if confirmed, is virtually impossible to reconcile with current galaxy formation model predictions. We show here that the implied UV luminosity density can be produced by a population of primordial black holes (PBH) of mass $M_{\rm PBH} = 10^{4-5} \, M_{\odot}$ residing in low-mass halos ($M_h \approx 10^{7} \, M_{\odot}$), and accreting at a moderate fraction of the Eddington luminosity, $\lambda_E \simeq 0.36$. These sources precede the first significant episodes of cosmic star formation. At later times, as star formation is ignited, PBH emission becomes comparable or subdominant with respect to the galactic one. Such a PBH+galaxy scenario reconciles the evolution of the UV LF from $z=25$ to $z=11$. If ultra-early sources are purely powered by accretion, this strongly disfavours seed production mechanisms requiring the presence of stars (massive/Pop III stars or clusters) or their UV radiation (direct collapse BHs), leaving PBH as the only alternative solution available so far. Alternative explanations, such as isolated, large clusters ($\approx 10^7 \, M_{\odot}$) of massive ($m_\star =10^3 M_{\odot}$) of Pop III are marginally viable, but require extreme and unlikely conditions, that can be probed via UV/FIR emission lines or gravitational waves.