The NUV transit of XO-3 b

TL;DR

This study analyzes near-UV and optical transits of XO-3 b, revealing a deeper NUV transit, a slight delay in NUV transit timing, and exploring atmospheric escape and magnetic effects with new X-ray data.

Contribution

First combined NUV, optical, and X-ray analysis of XO-3 b's transit, providing insights into atmospheric properties and magnetic interactions.

Findings

NUV transit depth is 30-70% deeper than optical.

NUV transit center is approximately 22 minutes late compared to optical.

X-ray data indicates an extremely small planetary mass-loss rate.

Abstract

Near-UV (NUV) measurements of exoplanet transits offer a means to probe atmospheric escape, cloud formation, and planetary magnetic fields. We examine a 2024 XMM-Newton Optical Monitor NUV observation of the transit of XO-3~b, a massive hot Jupiter on an eccentric orbit with a previously observed abnormally large NUV-absorbing atmosphere. We analyze this NUV data jointly with a concurrent ground-based optical observation and all TESS transit observations, and find a NUV transit depth of $R_{p,NUV}/R_{\star} = 0.1371^{+0.016}_{-0.019}$, which is 30-70% deeper than the optical transit. Although the optical transits do not show signs of transit timing variations, the transit center in the NUV is $22^{+13}_{-11}$ minutes late compared to the optical ephemeris. We investigate atmospheric escape as a potential explanation of the properties of this NUV transit by examining X-ray data from XMM-Newton, characterizing the X-ray luminosity of XO-3 for the first time and estimating an extremely small mass-loss rate of $\sim10^4$ g/s ($\sim10^{-19}$ M$_{\text{jup}}$/yr). Finally, we investigate the likelihood of an NUV-absorbent bow-shock by estimating the magnetic field of the planet. While such a mechanism is capable of producing NUV transit offsets on the order of tens of minutes, our analytic approximations predict an early rather than late transit, indicating a need for further magnetohydrodynamic simulations.