Beyond the [OIII]λ4363 auroral line: [NeIII]λ3868 as a direct tracer of electron temperature

Abstract

Auroral lines enable accurate measurements of chemical abundances in ionized gaseous nebulae thanks to their sensitivity to electron temperature. However, metal-enriched systems remain a challenge, as even deep observations cannot retrieve auroral lines due to their intrinsic faintness. To overcome this limitation, we present a novel approach to estimate electron temperatures in the conditions where the [OIII]λ4363 auroral line is barely detectable (Te < 11,000 K). This approach relies on the detection of [NeIII]λ3868 and [OIII]λ4959,5007, which are among the brightest rest-frame optical emission lines. By means of detailed photoionization models, we derive a tight relation between the O3Ne3[OIII]λ4959,5007/[NeIII]λ3868 ratio and the electron temperature weighted in the O++ dominated region. We test the validity of this relation in a large sample of galaxies that cover a wide range of redshifts z0-9 and extragalactic HII regions. Our results show that the O3Ne3 ratio, in combination with the O3O2 ratio (tracer of ionization), yields electron temperature estimates consistent within the uncertainties with those based on [OIII]λ4363. The proposed relation can be used to estimate electron temperature in the cool (equivalently high-metal) regime [6,000, 13,500 K] where the emissivity of [OIII]λ4363 drops drastically.