Out of oxygen: Extremely metal-poor galaxy candidates identified at 2.5 < z < 6.5 with deep JADES medium-band imaging
Abstract
JWST is beginning to uncover a population of extremely metal-poor galaxies (EMPGs, Z < 1\%~Z) at z > 3, mostly through serendipitous NIRSpec discoveries and blind slitless spectroscopy. To accelerate our understanding of pristine star formation, we further develop a methodology to identify EMPG candidates from photometry, using the extensive deep medium-band imaging from JADES. Our EMPG candidates at 2.5 < z < 6.5 exhibit strong photometric boosts by Hα, yet correspondingly weak boosts by [O III] + Hβ, likely indicating extremely low metallicity to explain their lack of [O III] emission. We further demand our EMPG candidates to have strong Balmer jumps, as revealed by medium-band imaging, to ensure that they are young starbursts, as opposed to broad-line AGN/LRDs, though contamination by dusty/dense-gas starbursts and highly-obscured AGN remains a concern. SED-fitting with near-pristine models (0.1-1\%~Z) indicates that our 22 EMPG candidates are low-mass (median M* ≈ 106.7~M), faint dwarf galaxies (MUV ≈ -16.6), with high ionizing photon production efficiencies (\, (ion, obs/(Hz\ erg-1)) ≈ 26.0). Hence these are plausible sites of near-pristine star formation, comprising 0.04-0.6\% of 2.5 < z < 6.5 galaxies at -19 < MUV < -16. We discuss this extremely metal-poor extension to the mass-metallicity relation. We forecast that deep (28 h) NIRCam slitless spectroscopy can identify bright EMPGs through strong Hβ but lack of [O III] emission, or secure the redshifts of fainter systems through Hα detections. Highly-multiplexed NIRSpec spectroscopy offers an alternate route to discovering the faintest pristine galaxies out to z=10, without requiring deep medium-band/MIRI imaging to identify secure candidates.
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