📝 SummarXiv

Abstract

Space-based photometry from missions such as TESS has revealed that many young delta Scuti stars exhibit regular high-frequency pulsation patterns. These pulsations provide a powerful means of inferring stellar properties, particularly ages, for pre-main-sequence and early main-sequence delta Scuti stars, for which traditional age-dating methods are poorly constrained. Realising this potential requires robust theoretical models that capture the complexities of stellar structure and evolution. We present a comprehensive grid of 25 million stellar pulsation models, computed using the MESA stellar evolution code and the GYRE oscillation code, tailored specifically to delta Scuti stars. The grid spans a wide range of masses, metallicities, and surface rotation velocities, and covers evolutionary phases from the early pre-main-sequence through the main sequence and into the post-main-sequence contraction phase. For each model, we compute hundreds of adiabatic pulsation frequencies for degrees l = 0-3, capturing p-modes, g-modes, f-modes, and their interactions through avoided crossings. Our analysis maps the behaviour of asteroseismic observables, including the large frequency separation (Delta nu) and the phase offset parameter (epsilon), across age, mass, and rotation. We investigate how these parameters change with evolutionary stage and revisit the scaling relations applicable to delta Scuti stars. This new model grid, which is publicly available, is designed to support the asteroseismology community in interpreting delta Scuti pulsations and in probing the evolution and internal structure of these stars. These improvements over previous model grids will allow for reliable age estimates and stronger constraints on stellar evolution pathways and the timing of planet formation across A- and F-type stellar populations.