What does this research mean for the field?

The giant exoplanet HATS-75 b possesses a remarkably low atmospheric metallicity and a supersolar carbon-to-oxygen ratio indicative of poor vertical mixing, with its transmission spectrum being significantly shaped by stellar contamination from unocculted starspots and faculae. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

To analyze the atmospheric properties of the exoplanet HATS-75 b and understand the effects of stellar contamination on its transmission spectrum.

April 21, 2026Open Access

GEMS JWST: HATS-75 b A Giant Planet with a Subsolar Metallicity Atmosphere Orbiting an M Dwarf

Key Points

To analyze the atmospheric properties of the exoplanet HATS-75 b and understand the effects of stellar contamination on its transmission spectrum.
Conducted observations of three transits of HATS-75 b using the NIRSpec PRISM instrument (0.6–5.3 μm).
Utilized atmospheric retrieval models to analyze transmission spectra and estimate metallicity and carbon-to-oxygen ratios.
Assessed effects of stellar heterogeneities such as unocculted starspots on observed spectra.
Achieved significant findings of low atmospheric metallicity (log[M/H] = -1.7±0.76) and a supersolar C/O ratio (C/O = 1.0±0.09).
Detected robust absorption signatures of CH4, CO, and CO2, with H2O showing only an upper limit due to stellar contamination.
Confirmed the impact of stellar surface variations on the transmission spectrum interpretation.

Abstract

Abstract HATS-75 b is one of the recently discovered Giant Exoplanets Around M-dwarf Stars (GEMS) with a transmission spectrum shaped by both its atmosphere and the active stellar surface it transits. As part of a JWST program studying seven GEMS, we observed three transits of HATS-75 b with the NIRSpec PRISM instrument (0.6–5.3 μ m). The planet’s spectra exhibit a slightly larger transit depth at shorter wavelengths, indicative of hazes or stellar contamination due to stellar heterogeneities outside the transit chord, i.e., the transit light source (TLS) effect. While both a hazy atmospheric model or TLS model can replicate the transmission spectrum, independent evidence (e.g., stellar rotation, spot-crossing events) favors a model that includes contamination from unocculted starspots and faculae. Within this stellar heterogeneity/TLS-based framework, atmospheric retrievals yield remarkably low atmospheric metallicity ( log M / H = − 1.7 4 − 0.76 + 0.92 ) and supersolar carbon-to-oxygen ( C / O = 1.0 4 − 0.09 + 0.40 ), which paired with a best-fit interior model with bulk metallicity of Z p = 0.20 ± 0.04 implies poor vertical mixing within the planet. Retrievals also detect robust absorption signatures of CH 4 , CO, and CO 2 . We obtain only an upper limit for H 2 O, consistent with its atmospheric spectral features being masked by stellar contamination. These results underscore the importance of accounting for stellar heterogeneity when interpreting exoplanet transmission spectra and highlight HATS-75 b as a significant asset to our understanding of giant exoplanets around M dwarfs with JWST.

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