The First Empirical Calibration of the MIR Abundance Diagnostic Ne23 with JWST

Abstract

Large surveys of galaxies in the local and high-redshift Universe have, traditionally, relied on the intensity of rest-optical emission lines from metal ions in the Interstellar Medium (ISM) to indirectly estimate the O/H abundance in the gas. However, these optical strong line diagnostics are also sensitive to the electron gas temperature (Te), resulting in large systematic uncertainties that inherently limit their utility as metallicity tracers, especially in dust-obscured and metal-rich environments. To this end, we provide the first empirical calibration of Ne23, a novel abundance diagnostic using the mid-infrared (MIR) Te-insensitive [Ne II]λ12.81μm and [Ne III]λ15.56μm fine-structure lines. We present new JWST/MIRI MRS observations of ten H II regions with optical measurements of Te and O/H from the CHAOS project, and we analyze MIRI observations of eight low-metallicity galaxies with similarly high-fidelity direct O/H. We measure Ne23 from 1D MIR spectra extracted from apertures matched to the ground-based spectroscopy used to obtain O/H, a method that is unfeasible from MIR spectra acquired on prior space-based observatories. From these nebulae, Ne23 is strongly correlated with O/H over 1.5 dex in 12+log(O/H). We calibrate the O/H-Ne23 relation from the empirical data, finding a scatter of just 0.06 dex in O/H at fixed Ne23. The O/H-Ne23 relation presented here provides a means to reliably estimate 12+log(O/H) from JWST/MIRI MRS observations of ionized nebulae out to z≈0.8, enabling new chemical abundance surveys of highly-attenuated regions and in the metal-rich ISM.