The Bubble Wall Velocity in Local Thermal Equilibrium with Full Effective Potential (2505.19584v1)

Abstract: In cosmological phase transitions, the bubble wall velocity is essential for electroweak baryogenesis and gravitational wave predictions. We develop a computational framework that directly determines the velocity within the local thermal equilibrium approximation, utilizing the full one-loop finite-temperature effective potential. This approach mitigates the errors introduced by using simplified bag model. We estimate the errors by comparing the results obtained using derived velocities-with kinetic energy fractions calculated from hydrodynamic integration-against those using fixed velocities, where kinetic energy fractions are derived from fitting formulas. We find that the fitting formulas retain reasonable accuracy when the assumed velocities align with the computed values. However, deviations grow as the velocity discrepancies increase, particularly in the deflagration regime, where relative errors reach 48% in peak frequency and 90% in peak value of gravitational wave spectrum. In contrast, the detonation regime exhibits significantly smaller discrepancies, with maximum deviations limited to 6% in peak frequency and 18% in peak spectrum.