Blackbodies Matter (2503.22799v1)

Abstract: We study line driven stellar winds using multifrequency, time-dependent radiation hydrodynamics. We compute the radiation force due to lines, the so called force multiplier, using precomputed photoionization tables and a time-dependent, local SED using a three band approximation within the hydro. We find that accounting for changes in the local SED changes the global properties of the flow. This is due to a combination of a change in the available momentum in the radiation field but also due to changes in the gas/radiation coupling mediated by the force multiplier. The acceleration can be suppressed, due to attenuation of UV flux but the force multiplier itself can be enhanced due to the overall SED hardening. We do not see evidence of a changing SED leading to formation or growth of azimuthal instabilities, as this effect appears subdominant to other instabilities in the wind. The computational methods presented can be extended to other outflow problems, notably multi-temperature disc winds and shocking in Wolf-Rayet stars.