Short-term events, such as stellar flares, produce intense bursts of high-energy radiation that break apart molecules in the upper atmosphere of the exoplanet, driving significant chemical changes. Over longer periods, prolonged exposure to strong stellar irradiation gradually heats the planet, leading to atmospheric escape and potential transformation in its structure and composition. To better understand these processes, we employ chemical disequilibrium modelling, radiative transfer simulations, and planetary evolution codes to analyse the interiors and atmospheres of gaseous exoplanets. By doing so, we aim to determine how these external influences shape their composition, structure, and observable characteristics, shedding light on their long-term atmospheric evolution.

• chemical disequilibrium
• exoplanets
• gas giants
• machine learning
• planetary evolution
• radiative transfer
• stellar events
• stellar flaring
• stellar irradiation

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