# Functional methods for false vacuum decay in real time

**Authors:** Wen-Yuan Ai, Bjorn Garbrecht, Carlos Tamarit

arXiv: 1905.04236 · 2019-12-17

## TL;DR

This paper develops a real-time path integral approach using complex saddle points and Lefschetz thimbles to compute false vacuum decay rates, including quantum corrections, in quantum mechanics and field theory.

## Contribution

It introduces a novel real-time method employing Picard-Lefschetz theory to evaluate quantum tunneling amplitudes with quantum corrections.

## Key findings

- Successfully computes decay rates matching known Euclidean results.
- Demonstrates the method on a quartic potential example.
- Provides a framework for real-time analysis of quantum tunneling.

## Abstract

We present the calculation of the Feynman path integral in real time for tunneling in quantum mechanics and field theory, including the first quantum corrections. For this purpose, we use the well-known fact that Euclidean saddle points in terms of real fields can be analytically continued to complex saddles of the action in Minkowski space. We also use Picard-Lefschetz theory in order to determine the middle-dimensional steepest-descent surface in the complex field space, constructed from Lefschetz thimbles, on which the path integral is to be performed. As an alternative to extracting the decay rate from the imaginary part of the ground-state energy of the false vacuum, we use the optical theorem in order to derive it from the real-time amplitude for forward scattering. While this amplitude may in principle be obtained by analytic continuation of its Euclidean counterpart, we work out in detail how it can be computed to one-loop order at the level of the path integral, i.e. evaluating the Gau{\ss}ian integrals of fluctuations about the relevant complex saddle points. To that effect, we show how the eigenvalues and eigenfunctions on a thimble can be obtained by analytic continuation of the Euclidean eigensystem, and we determine the path-integral measure on thimbles. This way, using real-time methods, we recover the one-loop result by Callan and Coleman for the decay rate. We finally demonstrate our real-time methods explicitly, including the construction of the eigensystem of the complex saddle, on the archetypical example of tunneling in a quasi-degenerate quartic potential.

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/1905.04236/full.md

## References

64 references — full list in the complete paper: https://tomesphere.com/paper/1905.04236/full.md

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Source: https://tomesphere.com/paper/1905.04236