Exploiting synergies between JWST and cosmic 21-cm observations to uncover star formation in the early Universe (2503.21687v1)

Abstract: In the current era of JWST, we continue to uncover a wealth of information about the Universe deep into the Epoch of Reionization. In this work, we run a suite of simulations using the code 21cmSPACE, to explore the astrophysical properties of galaxies in the early Universe, and their impact on high-redshift observables. We use multi-wavelength observational data including the global 21-cm signal and power spectrum limits from SARAS~3 and HERA respectively, present-day diffuse X-ray and radio backgrounds, and UV luminosity functions (UVLFs) from HST and JWST in the range $z=6-14.5$ to derive our constraints. We constrain a flexible model of halo-mass and redshift dependent star-formation efficiency (SFE), defined as the gas fraction converted into stars, and find that it is best described by little to no redshift evolution at $z\approx6-10$ and rapid evolution at $z\approx10-15$. We derive Bayesian functional posterior distributions for the SFE across this redshift range, inferring that a halo of mass $M_h=10^{10}\text{M}_\odot$ has an efficiency of $2-3\%$ at $z\lesssim10$, $12\%$ at $z=12$ and $26\%$ at $z=15$. We also find, through synergy between SARAS~3 and UVLFs, that the minimum circular velocity for star-formation in halos is $V_c = 16.9^{+25.7}_{-9.5}\text{km s}^{-1}$ or equivalently $\log_{10}(M_\text{crit}/\text{M}\odot) = 8.29^{+1.21}{-1.08}$ at $z=6$. Alongside these star-formation constraints, we find the X-ray and radio efficiencies of early galaxies to be $f_X = 0.5^{+6.3}_{-0.3}$ and $f_r \lesssim 11.7$ respectively, improving upon existing works that do not use UVLF data. Our results demonstrate the critical role of UVLFs in constraining the early Universe, and its synergies with 21-cm observations, alongside other multi-wavelength observational datasets.