No-go theorem for scalar-trispectrum-induced gravitational waves

Sebastian Garcia-Saenz; Lucas Pinol; Sébastien Renaux-Petel; Denis Werth

doi:10.1088/1475-7516/2023/03/057

No-go theorem for scalar-trispectrum-induced gravitational waves

Sebastian Garcia-Saenz, Lucas Pinol, Sébastien Renaux-Petel, Denis Werth

Research output: Contribution to journal › Article › peer-review

Abstract

We show that the contribution of the primordial trispectrum to the energy density of the scalar-induced stochastic gravitational wave background cannot exceed the one from the scalar power spectrum in conventional inflationary scenarios. Specifically, we prove in the context of scale-invariant theories that neither regular trispectrum shapes peaking in so-called equilateral configurations, nor local trispectrum shapes diverging in soft momentum limits, can contribute significantly. Indeed, those contributions are always bound to be smaller than an order-one (or smaller) number multiplying the relative one-loop correction to the scalar power spectrum, necessarily much smaller than unity in order for the theory to be under perturbative control. Since a no-go theorem is only worth its assumptions, we also briefly discuss a toy model for a scale-dependent scalar spectrum, which confirms the robustness of our no-go result.

Original language	English
Article number	057
Journal	Journal of Cosmology and Astroparticle Physics
Volume	2023
Issue number	3
DOIs	https://doi.org/10.1088/1475-7516/2023/03/057
Publication status	Published - 1 Mar 2023
Externally published	Yes

Keywords

cosmological perturbation theory
inflation
physics of the early universe
primordial gravitational waves (theory)

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10.1088/1475-7516/2023/03/057

Cite this

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title = "No-go theorem for scalar-trispectrum-induced gravitational waves",

abstract = "We show that the contribution of the primordial trispectrum to the energy density of the scalar-induced stochastic gravitational wave background cannot exceed the one from the scalar power spectrum in conventional inflationary scenarios. Specifically, we prove in the context of scale-invariant theories that neither regular trispectrum shapes peaking in so-called equilateral configurations, nor local trispectrum shapes diverging in soft momentum limits, can contribute significantly. Indeed, those contributions are always bound to be smaller than an order-one (or smaller) number multiplying the relative one-loop correction to the scalar power spectrum, necessarily much smaller than unity in order for the theory to be under perturbative control. Since a no-go theorem is only worth its assumptions, we also briefly discuss a toy model for a scale-dependent scalar spectrum, which confirms the robustness of our no-go result.",

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T1 - No-go theorem for scalar-trispectrum-induced gravitational waves

AU - Garcia-Saenz, Sebastian

AU - Pinol, Lucas

AU - Renaux-Petel, Sébastien

AU - Werth, Denis

PY - 2023/3/1

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N2 - We show that the contribution of the primordial trispectrum to the energy density of the scalar-induced stochastic gravitational wave background cannot exceed the one from the scalar power spectrum in conventional inflationary scenarios. Specifically, we prove in the context of scale-invariant theories that neither regular trispectrum shapes peaking in so-called equilateral configurations, nor local trispectrum shapes diverging in soft momentum limits, can contribute significantly. Indeed, those contributions are always bound to be smaller than an order-one (or smaller) number multiplying the relative one-loop correction to the scalar power spectrum, necessarily much smaller than unity in order for the theory to be under perturbative control. Since a no-go theorem is only worth its assumptions, we also briefly discuss a toy model for a scale-dependent scalar spectrum, which confirms the robustness of our no-go result.

AB - We show that the contribution of the primordial trispectrum to the energy density of the scalar-induced stochastic gravitational wave background cannot exceed the one from the scalar power spectrum in conventional inflationary scenarios. Specifically, we prove in the context of scale-invariant theories that neither regular trispectrum shapes peaking in so-called equilateral configurations, nor local trispectrum shapes diverging in soft momentum limits, can contribute significantly. Indeed, those contributions are always bound to be smaller than an order-one (or smaller) number multiplying the relative one-loop correction to the scalar power spectrum, necessarily much smaller than unity in order for the theory to be under perturbative control. Since a no-go theorem is only worth its assumptions, we also briefly discuss a toy model for a scale-dependent scalar spectrum, which confirms the robustness of our no-go result.

KW - cosmological perturbation theory

KW - inflation

KW - physics of the early universe

KW - primordial gravitational waves (theory)

U2 - 10.1088/1475-7516/2023/03/057

DO - 10.1088/1475-7516/2023/03/057

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No-go theorem for scalar-trispectrum-induced gravitational waves

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