Real-time dynamics of false vacuum decay
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We investigate false vacuum decay of a relativistic scalar field initialized in the metastable minimum of an asymmetric double-well potential. The transition to the true ground state is a well-defined initial-value problem in real time, which can be formulated in nonequilibrium quantum field theory on a closed time path. We employ the non-perturbative framework of the two-particle irreducible (2PI) quantum effective action at next-to-leading order in a large-N expansion. We also compare to classical-statistical field theory simulations on a lattice in the high-temperature regime. By this, we demonstrate that the real-time decay rates are comparable to those obtained from the conventional Euclidean (bounce) approach. In general, we find that the decay rates are time dependent. For a more comprehensive description of the dynamics, we extract a time-dependent effective potential, which becomes convex during the nonequilibrium transition process. By solving the quantum evolution equations for the one- and two-point correlation functions for vacuum initial conditions, we demonstrate that quantum corrections can lead to transitions that are not captured by classical-statistical approximations.
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Cited by 2 Pith papers
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Compact space catalysis of false vacuum decay and Schwinger effect
Below a critical compact volume, false vacuum decay proceeds via a new homogeneous bounce instead of the O(D) bubble, exponentially enhancing the rate and nucleating uniform field configurations.
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Compact space catalysis of false vacuum decay and Schwinger effect
For spatial volumes below a critical value in D compact dimensions, a new bounce distinct from Coleman's O(D) bubble mediates false vacuum decay, yielding homogeneous configurations and enhanced rates.
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