Asteroseismology and Buoyancy Glitch Inversion with Fourier Spectra of Gravity Mode Period Spacings

Abstract

We investigate the small, quasi-periodic modulations seen in the gravity-mode period spacings of pulsating stars. These ``wiggles'' are produced by buoyancy glitches -- sharp features in the buoyancy frequency (N) caused by composition transitions and the convective-radiative interface. Our method takes the Fourier transform of the period-spacing series, FT( Pk) as a function of radial order k. We show that FT( Pk) traces the radial derivative of the normalized glitch profile δ N/N with respect to the normalized buoyancy radius; peaks in FT( Pk) therefore pinpoint jump/drop locations in N and measure their sharpness. We also note that the Fourier transform of relative period perturbations (deviations from asymptotic values), FT(δ P/P), directly recovers the absolute value of the glitch profile |δ N/N|, enabling a straightforward inversion for the internal structure. The dominant FT( Pk) frequency correlates tightly with central hydrogen abundance (Xc) and thus with stellar age for slowly pulsating B-stars, with only weak mass dependence. Applying the technique to MESA stellar models and to observed slowly pulsating B-stars and γ Dor pulsators, we find typical glitch amplitudes δ N/N 0.01 and derivative magnitudes 0.1, concentrated at chemical gradients and the convective boundary. This approach enables fast, ensemble asteroseismology of g-mode pulsators, constrains internal mixing and ages, and can be extended to other classes of pulsators, with potential links to tidal interactions in binaries.

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