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Abstract:

We report the discovery of a remarkably large and luminous line-emitting nebula extending on either side of the Balmer-break galaxy JADES-GS-518794 at , detected with James Webb Space Telescope (JWST)/NIRCam imaging in [O iii]4959, 5007 and H α and spectroscopically confirmed with NIRCam/wide-field slitless spectroscopy, thanks to the pure-parallel programme Slitless Areal Pure Parallel HIgh-Redshift Emission Survey. The end-to-end velocity offset is . Nebulae with such large sizes and high luminosities (25 pkpc diameter, ) are routinely observed around bright quasars, unlike JADES-GS-518794. With a stellar mass of , this galaxy is at the knee of the mass function at . Its star formation rate declined for some time (10–100 Myr prior to observation), followed by a recent (10 Myr) upturn. This system is part of a candidate large-scale galaxy overdensity, with an excess of Balmer-break galaxies compared to the field (3σ). We discuss the possible origin of this nebula as material from a merger or gas expelled by an active galactic nucleus (AGN). The symmetry of the nebula, its bubble-like morphology, kinematics, high luminosity, and the extremely high equivalent width of [O iii] together favour the AGN interpretation. Intriguingly, there may be a physical connection between the presence of such a large, luminous nebula and the possible metamorphosis of the central galaxy towards quenching.

Abstract:

The presence of Active Galactic Nuclei (AGNs) in low mass () galaxies at high redshift has been established, and it is important to characterize these objects and the impact of their feedback on the host galaxies. In this paper, we apply the Spectral Energy Distribution (SED) fitting code beagle-agn to SMACS S06355, a z7.66 Type-II AGN candidate from the JWST NIRSpec Early Release Observations. This object’s spectrum includes a detection of the [Ne iv] line, indicating an obscured AGN due to its high ionization potential energy (63 eV). We use beagle-agn to simultaneously model the Narrow Line Region (NLR) AGN and star-forming galaxy contributions to the observed line fluxes and photometry. Having a high-ionization emission line allows the contribution of the NLR to the remaining lines to be probabilistically disentangled. The H ii region metallicity is derived to be 12 + log(O/H) = . Assuming that the Neon-to-Oxygen abundance is similar to solar we derive a high NLR metallicity of 12 + log(O/H) = , with the 2 lower-limit extending to 12 + log(O/H)8.00, showing the derivation is uncertain. We discuss this result with respect to non-solar Neon abundances that might boost the inferred NLR metallicity. The NLR metallicity places SMACS S06355 in a comparable region of the mass–metallicity plane to intermediate (1.5z3.0) redshift obscured AGN. Our derived accretion disc luminosity, log() = , is moderately high yet still uncertain. We highlight that deviations between bolometric luminosity calibrations and model grid tracks become enhanced at low metallicities.

Abstract:

Disc winds play a crucial role in many accreting astrophysical systems across all scales. In accreting white dwarfs (AWDs) and active galactic nuclei (AGNs), radiation pressure on spectral lines is a promising wind-driving mechanism. However, the efficiency of line driving is extremely sensitive to the ionization state of the flow, making it difficult to construct a reliable physical picture of these winds. Recently, we presented the first radiation-hydrodynamics simulations for AWDs that incorporated detailed, multidimensional ionization calculations via fully frequency-dependent radiative transfer, using the sirocco code coupled to pluto. These simulations produced much weaker line-driven winds ( for our adopted parameters) than earlier studies using more approximate treatments of ionization and radiative transfer (which yielded ). One remaining limitation of our work was the assumption of an isothermal outflow. Here, we relax this by adopting an ideal gas equation of state and explicitly solving for the multidimensional temperature structure of the flow. In the AWD setting, accounting for the thermal state of the wind does not change the overall conclusions drawn from the isothermal approximation. Our new simulations confirm the line-driving efficiency problem: the predicted outflows are too highly ionized, meaning they neither create optimal driving conditions nor reproduce the observed ultraviolet wind signatures. Possible solutions include wind clumping on subgrid scales, a softer-than-expected spectral energy distribution or additional driving mechanisms. With the physics now built into our simulations, we are well equipped to also explore line-driven disc winds in AGN.