📝 SummarXiv

Abstract

We investigate the evolution and formation of double-layered vacuum bubbles during cosmological phase transitions with mltiple vacua. Using a semiclassical approach with initial velocity fluctuations, we demonstrate that under certain conditions, quantum effects do not lead to the formation of double-layered vacuum bubbles, while flyover transitions allow for their stable formation by overcoming successive potential barriers. The evolution of these bubbles, including wall acceleration, collisions, and the formation of trapped regions, is explored through numerical simulations. Our results show that the dynamics of double-layered bubbles differ significantly from standard single-wall bubbles, with implications for cosmological observables such as gravitational wave production and baryogenesis. These findings indicate that flyover transitions represent a complementary decay mechanism to the conventional quantum tunneling process.