Disentangling the co-evolution of galaxies and supermassive black holes with PRIMA

TL;DR

PRIMA, a proposed far-infrared space observatory, will enable detailed study of galaxy and black hole co-evolution by detecting dusty galaxies and analyzing their gas, dust, and star formation properties across cosmic time.

Contribution

This work demonstrates how PRIMA's multi-band photometry and spectroscopy can surpass previous IR missions in studying galaxy evolution and black hole activity.

Findings

PRIMA can detect galaxies down to 10^11 L_sun beyond cosmic noon at z=4.

Spectroscopic follow-up will measure star formation and black hole accretion rates up to z=2.

PRIMA can accurately determine gas metallicities and outflow rates in distant galaxies.

Abstract

The most active phases of star formation and black hole accretion are strongly affected by dust extinction, making far-infrared (far-IR) observations the best way to disentangle and study the co-evolution of galaxies and super massive black holes. The plethora of fine structure lines and emission features from dust, ionised and neutral atomic and warm molecular gas in the rest-frame mid- and far-IR provide unmatched diagnostic power to determine the properties of gas and dust, measure gas-phase metallicities and map cold galactic outflows in even the most obscured galaxies. By combining multi-band photometric surveys with low and high-resolution far-IR spectroscopy, the PRobe far-Infrared Mission for Astrophysics (PRIMA), a concept for a far-IR, 1.8m-diameter, cryogenically cooled observatory, will revolutionise the field of galaxy evolution by taking advantage of this IR toolkit to find and study dusty galaxies across galactic time. In this work, we make use of the phenomenological simulation SPRITZ and the Santa Cruz semi-analytical model to describe how a moderately deep multi-band PRIMA photometric survey can easily reach beyond previous IR missions to detect and study galaxies down to $10^{11}\,L_{\odot}$ beyond cosmic noon and at least up to z=4, even in the absence of gravitational lensing. By decomposing the spectral energy distribution (SED) of these photometrically selected galaxies, we show that PRIMA can be used to accurately measure the relative AGN power, the mass fraction contributed by polycyclic aromatic hydrocarbon (PAH) and the total IR luminosity. At the same time, spectroscopic follow up with PRIMA will allow to trace both the star formation and black hole accretion rates (SFR, BHAR), the gas phase metallicities and the mass outflow rates of cold gas in hundreds to thousands of individual galaxies to z=2.