Evolving Atmospheric Ion Escape from Kepler-1649 b and c: Power-Law Trends in Atmospheric Loss
Abstract
Rocky planets orbiting M-dwarf stars are prime targets for characterizing terrestrial atmospheres, yet their long-term evolution under intense stellar winds and high-energy radiation remains poorly understood. The Kepler-1649 system, which hosts two terrestrial exoplanets orbiting an M5V star, presents a valuable opportunity to explore atmospheric evolution in the extreme environments characteristic of M-dwarf stellar systems. In this Letter we show that both planets could have retained atmospheres over gigayear timescales. Using a multi-species magnetohydrodynamic model, we simulate atmospheric ion escape driven by stellar winds and extreme ultraviolet radiation from 0.7 to 4.8 Gyrs. The results show that total ion escape rates follow a power-law decline ($\propto \tau^{-1.6}$ for Kepler-1649 b, $\propto \tau^{-1.5}$ for Kepler-1649 c$\,$), with O$^{+}$ dominating atmospheric loss (76.8%-98.7%). The escape rates at 4.8 Gyrs are two orders of magnitude lower than those during the early epochs ($1.9\times10^{27}$ s$^{-1}$ at 0.7 Gyr vs. $3.0\times10^{25}$ s$^{-1}$ at 4.8 Gyrs for planet b$\,$), while planet b consistently exhibits 1.1-1.9$\times$ higher O$^{+}$ escape rates than planet c due to its closer orbit (0.051 AU vs. 0.088 AU). Despite substantial early atmospheric erosion, both planets may still retain significant atmospheres, suggesting the potential for long-term habitability. These findings offer predictive insight into atmospheric retention in M-dwarf systems and inform future JWST observations aimed at refining habitability assessments.