A Stellar Magnesium to Silicon ratio in the atmosphere of an exoplanet

TL;DR

This study measures elemental ratios in an ultra-hot Jupiter's atmosphere, showing that its rock-forming element ratios mirror stellar values, thus validating assumptions used in planetary formation models.

Contribution

First direct measurement of refractory element ratios in an exoplanet atmosphere confirming they reflect stellar compositions.

Findings

Mg/Si, Fe/Mg, Si/Fe ratios match stellar values

Refractory-to-volatile ratio is about twice that of the star

Atmospheric composition supports stellar-proxy assumption for planetary models

Abstract

The elemental compositions of exoplanets encode information about their formation environments and internal structures. While volatile ratios such as carbon-to-oxygen (C/O) are used to trace formation location, the rock-forming elements - magnesium (Mg), silicon (Si), and iron (Fe) - govern interior mineralogy and are commonly assumed to reflect the host star's abundances. Yet this assumption remains largely untested. Ultra-hot Jupiters, gas-giant exoplanets with dayside temperatures above 3000 K, provide rare access to refractory elements that remain gaseous. Here we present high-resolution thermal emission spectroscopy of the exoplanet WASP-189b (Teq = 3354^{+27}_{-34} K) obtained with the Immersion Grating Infrared Spectrometer (IGRINS) on Gemini South. We detect neutral iron (Fe I), magnesium (Mg I), silicon (Si I), water (H_2O), carbon monoxide (CO), and hydroxyl (OH) at signal-to-noise ratios exceeding 4, and retrieve their elemental abundances. We show that the Mg/Si, Fe/Mg, and Si/Fe ratios are consistent with stellar values, while the refractory-to-volatile ratio is enhanced by roughly a factor of ~2. These findings demonstrate that giant-planet atmospheres can preserve stellar-like rock-forming ratios, providing an empirical validation of the stellar-proxy assumption that underpins planetary composition and formation models across exoplanet systems.