Challenges for large-field inflation and moduli stabilization

Wilfried Buchmüller; Emilian Dudas; Lucien Heurtier; Alexander Westphal; Clemens Wieck; Martin Wolfgang Winkler

doi:10.1007/JHEP04(2015)058

Challenges for large-field inflation and moduli stabilization

Wilfried Buchmüller
, Emilian Dudas
, Lucien Heurtier
, Alexander Westphal
, Clemens Wieck
, Martin Wolfgang Winkler

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Abstract: We analyze the interplay between Kähler moduli stabilization and chaotic inflation in supergravity. While heavy moduli decouple from inflation in the supersymmetric limit, supersymmetry breaking generically introduces non-decoupling effects. These lead to inflation driven by a soft mass term, m_φ² ∼ mm_3/2, where m is a supersymmetric mass parameter. This scenario needs no stabilizer field, but the stability of moduli during inflation imposes a large supersymmetry breaking scale, m_3/2 ≫ H, and a careful choice of initial conditions. This is illustrated in three prominent examples of moduli stabilization: KKLT stabilization, Kähler Uplifting, and the Large Volume Scenario. Remarkably, all models have a universal effective inflaton potential which is flattened compared to quadratic inflation. Hence, they share universal predictions for the CMB observables, in particular a lower bound on the tensor-to-scalar ratio, r ≳ 0.05.

langue originale	Anglais
Numéro d'article	58
journal	Journal of High Energy Physics
Volume	2015
Numéro de publication	4
Les DOIs	https://doi.org/10.1007/JHEP04(2015)058
état	Publié - 1 avr. 2015

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title = "Challenges for large-field inflation and moduli stabilization",

abstract = "Abstract: We analyze the interplay between K{\"a}hler moduli stabilization and chaotic inflation in supergravity. While heavy moduli decouple from inflation in the supersymmetric limit, supersymmetry breaking generically introduces non-decoupling effects. These lead to inflation driven by a soft mass term, mφ2 ∼ mm3/2, where m is a supersymmetric mass parameter. This scenario needs no stabilizer field, but the stability of moduli during inflation imposes a large supersymmetry breaking scale, m3/2 ≫ H, and a careful choice of initial conditions. This is illustrated in three prominent examples of moduli stabilization: KKLT stabilization, K{\"a}hler Uplifting, and the Large Volume Scenario. Remarkably, all models have a universal effective inflaton potential which is flattened compared to quadratic inflation. Hence, they share universal predictions for the CMB observables, in particular a lower bound on the tensor-to-scalar ratio, r ≳ 0.05.",

keywords = "Cosmology of Theories beyond the SM, Supergravity Models, Superstring Vacua, Supersymmetry Breaking",

author = "Wilfried Buchm{\"u}ller and Emilian Dudas and Lucien Heurtier and Alexander Westphal and Clemens Wieck and Winkler, \{Martin Wolfgang\}",

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T1 - Challenges for large-field inflation and moduli stabilization

AU - Buchmüller, Wilfried

AU - Dudas, Emilian

AU - Heurtier, Lucien

AU - Westphal, Alexander

AU - Wieck, Clemens

AU - Winkler, Martin Wolfgang

PY - 2015/4/1

Y1 - 2015/4/1

N2 - Abstract: We analyze the interplay between Kähler moduli stabilization and chaotic inflation in supergravity. While heavy moduli decouple from inflation in the supersymmetric limit, supersymmetry breaking generically introduces non-decoupling effects. These lead to inflation driven by a soft mass term, mφ2 ∼ mm3/2, where m is a supersymmetric mass parameter. This scenario needs no stabilizer field, but the stability of moduli during inflation imposes a large supersymmetry breaking scale, m3/2 ≫ H, and a careful choice of initial conditions. This is illustrated in three prominent examples of moduli stabilization: KKLT stabilization, Kähler Uplifting, and the Large Volume Scenario. Remarkably, all models have a universal effective inflaton potential which is flattened compared to quadratic inflation. Hence, they share universal predictions for the CMB observables, in particular a lower bound on the tensor-to-scalar ratio, r ≳ 0.05.

AB - Abstract: We analyze the interplay between Kähler moduli stabilization and chaotic inflation in supergravity. While heavy moduli decouple from inflation in the supersymmetric limit, supersymmetry breaking generically introduces non-decoupling effects. These lead to inflation driven by a soft mass term, mφ2 ∼ mm3/2, where m is a supersymmetric mass parameter. This scenario needs no stabilizer field, but the stability of moduli during inflation imposes a large supersymmetry breaking scale, m3/2 ≫ H, and a careful choice of initial conditions. This is illustrated in three prominent examples of moduli stabilization: KKLT stabilization, Kähler Uplifting, and the Large Volume Scenario. Remarkably, all models have a universal effective inflaton potential which is flattened compared to quadratic inflation. Hence, they share universal predictions for the CMB observables, in particular a lower bound on the tensor-to-scalar ratio, r ≳ 0.05.

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KW - Supergravity Models

KW - Superstring Vacua

KW - Supersymmetry Breaking

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Challenges for large-field inflation and moduli stabilization

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