# Quantum Break-Time of de Sitter

**Authors:** Gia Dvali, Cesar Gomez, and Sebastian Zell

arXiv: 1701.08776 · 2017-11-01

## TL;DR

This paper investigates the quantum break-time of de Sitter space by modeling it as a coherent state of gravitons, revealing how quantum effects lead to a finite lifetime and impose constraints on the cosmological constant.

## Contribution

It introduces a quantum coherent state model of de Sitter space that captures quantum effects beyond semi-classical approximations, deriving the quantum break-time and its dependence on particle species.

## Key findings

- Quantum break-time proportional to de Sitter radius and graviton number N
- Quantum effects violate de Sitter symmetry and cause finite lifetime
- Quantum break-time inversely related to number of particle species

## Abstract

The quantum break-time of a system is the time-scale after which its true quantum evolution departs from the classical mean field evolution. For capturing it, a quantum resolution of the classical background - e.g., in terms of a coherent state - is required. In this paper, we first consider a simple scalar model with anharmonic oscillations and derive its quantum break-time. Next, we apply these ideas to de Sitter space. We formulate a simple model of a spin-2 field, which for some time reproduces the de Sitter metric and simultaneously allows for its well-defined representation as quantum coherent state of gravitons. The mean occupation number $N$ of background gravitons turns out to be equal to the de Sitter horizon area in Planck units, while their frequency is given by the de Sitter Hubble parameter. In the semi-classical limit, we show that the model reproduces all the known properties of de Sitter, such as the redshift of probe particles and thermal Gibbons-Hawking radiation, all in the language of quantum $S$-matrix scatterings and decays of coherent state gravitons. Most importantly, this framework allows to capture the $1/N$-effects to which the usual semi-classical treatment is blind. They violate the de Sitter symmetry and lead to a finite quantum break-time of the de Sitter state equal to the de Sitter radius times $N$. We also point out that the quantum-break time is inversely proportional to the number of particle species in the theory. Thus, the quantum break-time imposes the following consistency condition: Older and species-richer universes must have smaller cosmological constants. For the maximal, phenomenologically acceptable number of species, the observed cosmological constant would saturate this bound if our Universe were $10^{100}$ years old in its entire classical history.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1701.08776/full.md

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/1701.08776/full.md

## References

24 references — full list in the complete paper: https://tomesphere.com/paper/1701.08776/full.md

---
Source: https://tomesphere.com/paper/1701.08776