# Measuring the Inflaton Coupling in the CMB

**Authors:** Marco Drewes

arXiv: 1903.09599 · 2022-09-30

## TL;DR

This paper explores how future CMB observations can constrain the inflaton's coupling to other fields during reheating, providing insights into the microphysics of inflation without detailed particle physics models.

## Contribution

It identifies conditions under which inflaton couplings can be constrained from CMB data, linking observable parameters to fundamental physics during reheating.

## Key findings

- Inflaton coupling constraints depend on the effective potential being approximately parabolic.
- Couplings smaller than the electron Yukawa coupling are consistent with the conditions.
- Measuring the scalar-to-tensor ratio at 10^{-3} can reveal inflaton coupling magnitudes.

## Abstract

We study the perspectives to extract information about the microphysical parameters that governed the reheating process after cosmic inflation from CMB data. We identify conditions under which the inflaton coupling to other fields can be constrained for a given model of inflation without having to specify the details of the particle physics theory within which this model is realised. This is possible when the effective potential during reheating is approximately parabolic, and when the coupling constants are smaller than an upper bound that is determined by the ratios between the inflaton mass and the Planck mass or the scale of inflation. We consider scalar, Yukawa, and axion-like interactions and estimate that these conditions can be fulfilled if the inflaton coupling is comparable to the electron Yukawa coupling or smaller, and if the inflaton mass is larger than $10^5$ GeV. Constraining the order of magnitude of the coupling constant requires measuring the scalar-to-tensor ratio at the level of $10^{-3}$, which is possible with future CMB observatories. Such a measurement would provide an important clue to understand how a given model of inflation may be embedded into a more fundamental theory of nature.

## Full text

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## Figures

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## References

157 references — full list in the complete paper: https://tomesphere.com/paper/1903.09599/full.md

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Source: https://tomesphere.com/paper/1903.09599