Probing habitable regions with SRG/eROSITA

Abstract

Stellar high-energy radiation is a key driver of atmospheric erosion and evolution in exoplanets, directly affecting their long-term habitability. We present a comprehensive study on stellar high-energy radiation and its impact on exoplanetary atmospheres, leveraging data from the SRG/eROSITA all-sky survey. Our sample consists of 3750 main-sequence stars identified by cross-matching with Gaia DR3. Utilizing X-ray spectral fits from the eROSITA catalog, we computed X-ray (LX) and combined extreme-ultraviolet (EUV) luminosities (LEUV), which we used to derive XUV fluxes at the habitable zone (FXUV,HZ). We find that the majority of stars in our sample are significantly more XUV-active than the Sun, with habitable zone fluxes ranging from 100 to 105 erg~cm-2~s-1. The ratio of LXUV/Lbol is found to be higher for cooler, magnetically active stars, highlighting their potentially hazardous nature for planetary atmospheres. Applying the energy-limited escape model, we computed atmospheric mass-loss rates for hypothetical earth-like planets located at the habitable zone of each star. We also present local maps for distances up to 500~pc of the average XUV flux, revealing ``hazard zones'' where stellar radiation could significantly influence planetary atmospheric evolution. This work demonstrates the power of X-ray surveys in constraining the high-energy environments of exoplanets and underscores the critical role of stellar activity in planetary habitability.