Physics – High Energy Physics – High Energy Physics - Phenomenology
Scientific paper
1995-10-24
Phys.Rev. D52 (1995) 6717-6729
Physics
High Energy Physics
High Energy Physics - Phenomenology
13 Figures avalaible by fax on request. Accepted for publication in Phys. Rev. D
Scientific paper
10.1103/PhysRevD.52.6717
One possible way in which phase transitions in the early universe may have ocurred is via nucleation of bubbles of the new phase (true vacuum) in the old phase (false vacuum). The technique most widely used to compute the probability of bubble nucleation is based on instanton methods in the context of the semiclassical approximation. At zero temperature in (3+1) dimensions the nucleation rate is dominated by the O(4) symmetric instanton, a sphere of radius $R$, while at temperatures $T >> R^{-1}$, the decay is dominated by a ``cylindrical'' (static) instanton wtih O(3) invariance. There has been discussion in the literature as to whether the transition between these two regimens would be first order (discontinuity in the first derivative of the nucleation rate at the transition temperature $T_{c}$), or second order (continuity of the first derivative, but discontinuity of the second derivative at $T_{c}$). In this paper we obtain the finite temperature solutions corresponding to the quantum and the thermal regimes, and compute their action as a function of the temperature for different values of the wall thickness in a $\varphi^{4}$ potential. Our results indicate that only for the cases of very large wall thickness a second order transition takes place, while for all the other cases a first order transition occurs
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