Mapping Jet-Gas Coupling and energetic ionized outflows in High-Redshift Radio Galaxies with JWST/NIRSpec (2508.06707v1)

Abstract: We present spatially resolved maps of morphology, kinematics, and energetics of warm ionized gas in six powerful radio galaxies at z=3.5-4, using JWST/NIRSpec IFU to quantify jet-driven feedback in the early universe. All sources exhibit broad [OIII] emission-line profiles with W80 (line width) values of 950-2500 km/s across $\sim$10s of kpc, signifying large-scale outflows. The outflowing nebulae are preferentially aligned with the radio jet axis, suggesting jet-driven origin. On average, the regions with the broadest lines and highest velocities are co-spatial with radio lobes or cores, and exhibit the strongest kinetic power. Ionized gas masses associated with the outflows span 1 to 8 $\times 10^{9} \ M_\odot$, with total mass outflow rates of 80-950 Msun/yr and kinetic powers between 10^{43.2} and 10^{45.0} erg/s. The outflow kinetic power corresponds to 0.15%-2% of the AGN bolometric luminosity, sufficient to impact galaxy evolution. However, only $\lesssim 1$\% of the jet mechanical energy couples to the warm ionized gas via outflows, consistent with predictions from hydrodynamic simulations. A large fraction of the jet energy may instead reside in shock-heated hot gas, supported by X-ray detection, or used to thermalize the gas and produce the observed emission-line nebulae. Our results demonstrate that radio jets in massive, gas-rich systems at high-redshift can inject significant kinetic and thermal energy to the surroundings, providing direct evidence for jet-driven feedback operating during the peak epoch of galaxy formation.