Abstract
We derive a general quantum field theoretic formula for the force acting on expanding bubbles of a first order phase transition in the early Universe setting. In the thermodynamic limit the force is proportional to the entropy increase across the bubble of active species that exert a force on the bubble interface. When local thermal equilibrium is attained, we find a strong friction force which grows as the Lorentz factor squared, such that the bubbles quickly reach stationary state and cannot run away. We also study an opposite case when scatterings are negligible across the wall (ballistic limit), finding that the force saturates for moderate Lorentz factors thus allowing for a runaway behavior. We apply our formalism to a massive real scalar field, the standard model and its simple portal extension. For completeness, we also present a derivation of the renormalized, one-loop, thermal energy-momentum tensor for the standard model and demonstrate its gauge independence.
| Original language | English |
|---|---|
| Article number | 70 |
| Number of pages | 48 |
| Journal | Journal of High Energy Physics |
| Volume | 2021 |
| DOIs | |
| Publication status | Published - 21 May 2020 |
Bibliographical note
65 pages (33 pages main text + 32 pages appendix and references), 15 figures, v2: improved discussion, clarifications added, matches published versionKeywords
- Spontaneous Symmetry Breaking
- Cosmology of Theories beyond the SM
- Thermal Field Theory
- Beyond Standard Model