Insight into the starburst nature of Galaxy GN-z11 with JWST MIRI spectroscopy
J. Álvarez-Márquez, Alejandro Crespo Gómez, L. Colina, D. Langeroodi, R. Marques-Chaves, C. Prieto-Jiménez, Arjan Bik, A. Alonso-Herrero, L. Boogaard, Luca Costantin, M. García-Marín, Steven Gillman, J. Hjorth, E. Iani, Iris Jermann, Á. Labiano, Jens Melinder, R. A. Meyer, G. Östlin, P. G. Pérez-González, Pierluigi Rinaldi, Fabian Walter, P. van der Werf, G.M. Wright
Abstract
This paper presents a deep MIRI/JWST medium-resolution spectroscopy (MRS) covering the rest-frame optical spectrum of the GN-z11 galaxy. The [O III] 5008 Å and H α emission lines are detected and spectroscopically resolved. The line profiles are well modeled by a narrow Gaussian component with intrinsic full widths at half maximum of 189 ± 25 and 231 ± 52 km s −1 , respectively. We do not find any evidence of a dominant broad H α emission line component tracing a broad-line region in a type 1 active galactic nucleus (AGN). The existence of an accreting black hole dominating the optical continuum and emission lines of GN-z11 is not compatible with the measured H α and [O III] 5008 Å luminosities. If the well-established relations for low- z AGNs apply in GN-z11, the [O III] 5008 Å and H α luminosities would imply extremely high super-Eddington ratios ( λ E > 290), and bolometric luminosities ∼20 times those derived from the UV/optical continuum. However, a broad (∼430–470 km s −1 ) and weak (< 20–30%) H α line component, tracing a minor AGN contribution in the optical, cannot be completely ruled out with the sensitivity of the current data. The physical and excitation properties of the ionized gas are consistent with a low-metallicity starburst with a star formation rate of 24 ± 3 M ⊙ yr −1 . The electron temperature of the ionized gas is T e (O ++ ) = 14 000 ± 2100 K, while the direct- T e gas-phase metallicity is 12 + log(O/H) = 7.91 ± 0.07 ( Z = 0.17 ± 0.03 Z ⊙ ). The optical line ratios locate GN-z11 in the starburst or AGN region, but they are more consistent with those of local low-metallicity starbursts and high- z luminous galaxies detected at redshifts similar to GN-z11. We conclude that the MRS optical spectrum of GN-z11 is consistent with that of a massive, compact, and low-metallicity starburst galaxy. Its high star formation and stellar mass surface densities are close to those of the densest stellar clusters, and we therefore speculate that GN-z11 might undergo a feedback-free, highly efficient starburst phase. Additional JWST data are needed to validate this scenario and other recently proposed alternatives to explain the existence of bright compact galaxies in the early Universe.