The Roasting Marshmallows Program with IGRINS on Gemini South V: Atmosphere of MASCARA-1b is Enriched in Refractory Elements

Abstract

Ultra-hot Jupiters (UHJs; T eq 2000 K) enable simultaneous detection of volatile (ice-forming) and refractory (rock-forming) species in planetary atmospheres, providing a powerful diagnostic of planet formation and atmospheric processing. We present a comprehensive high-resolution cross-correlation spectroscopy (HRCCS) analysis of the UHJ MASCARA-1b (T eq ≈ 2600 K) using the IGRINS and IGRINS-2 spectrographs. We detect robust (SNR>4) signals from H2O, CO, OH, Fe I, Mg I, Ca I, and Ti I, marking the most complete atmospheric inventory of MASCARA-1b to date. Using a chemically consistent atmospheric inference framework, we constrain elemental abundances to a typical precision of ≈0.2 dex, retrieving a solar atmospheric metallicity ([M/H] = 0.07+0.17-0.13 ≈ 1.2× solar), a C/O ratio (C/O = 0.65+0.08-0.08) consistent with solar value (C/O = 0.59), an enhanced refractory abundance ([R/H] = 0.40+0.23-0.17 ≈ 2.5× solar; ≈ 3.8× stellar), and a moderately super-solar refractory-to-volatile ratio ([R/V] = 0.36+0.11-0.09 ≈ 2.3× solar). Comparison with formation models suggests that MASCARA-1b most likely accreted material between the soot-H2O or H2O-CO snowlines (at 68\% confidence). We additionally find stellar values for atmospheric Ti/Mg and Ca/Mg ratios (at 68\% confidence). The Mg/Fe is also found to be consistent with stellar value at 95\% confidence. Therefore, we do not find strong indication of nightside cold trapping in MASCARA-1b. As homogeneous refractory-to-volatile measurements expand across the UHJ population, particularly with upcoming Extremely Large Telescopes, these diagnostics will enable statistically robust tests of emerging trends in giant planet formation and atmospheric evolution.