In N+1 dimensions, false vacuum decay at zero temperature is dominated by the O(N+1)-symmetric instanton, a sphere of radius ${\mathit{R}}_0$, whereas at temperatures T≫${\mathit{R}}_0^{\mathrm{-}1}$, the decay is dominated by a ‘‘cylindrical’’ (static) O(N)-symmetric instanton. We study the transition between these two regimes in the thin wall approximation. Taking an O(N)-symmetric ansatz for the instantons, we show that for N=2 and N=3 new periodic solutions exist in a finite temperature range in the neighborhood of T∼${\mathit{R}}_0^{\mathrm{-}1}$. However, these solutions have a higher action than the spherical or the cylindrical one. This suggests that there is a sudden change (a first order transition) in the derivative of the nucleation rate at a certain temperature ${\mathit{T}}_{\mathrm{*}}$, when the static instanton starts dominating. For N=1, on the other hand, the new solutions are dominant and they smoothly interpolate between the zero temperature instanton and the high temperature one, so the transition is of second order. The determinantal prefactors corresponding to the ‘‘cylindrical’’ instantons are discussed, and it is pointed out that the entropic contributions from massless excitations corresponding to deformations of the domain wall give rise to an exponential enhancement of the nucleation rate for T≫${\mathit{R}}_0^{\mathrm{-}1}$.

• Received 6 January 1994

DOI:https://doi.org/10.1103/PhysRevD.49.5497