Frame covariant nonminimal multifield inflation

Frame covariant nonminimal multifield inflation

We introduce a frame-covariant formalism for inflation of scalar-curvature theories by adopting a differential geometric approach which treats the scalar fields as coordinates living on a field-space manifold. This ensures that our description of inflation is both conformally and reparameterization...

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Main Authors: Sotirios Karamitsos, Apostolos Pilaftsis
Format: Article
Language:English
Published: Elsevier 2018-02-01
Series:Nuclear Physics B
Online Access:http://www.sciencedirect.com/science/article/pii/S0550321317304005
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spelling doaj-7d1926d66e4a434ea10979e8c5bfd0ad2020-11-25T03:40:01ZengElsevierNuclear Physics B0550-32132018-02-0192721925410.1016/j.nuclphysb.2017.12.015Frame covariant nonminimal multifield inflationSotirios Karamitsos0Apostolos Pilaftsis1Consortium for Fundamental Physics, School of Physics and Astronomy, University of Manchester, Manchester M13 9PL, United Kingdom; Corresponding author.Consortium for Fundamental Physics, School of Physics and Astronomy, University of Manchester, Manchester M13 9PL, United Kingdom; PRISMA Cluster of Excellence & Mainz Institute for Theoretical Physics, Johannes Gutenberg University, 55099 Mainz, GermanyWe introduce a frame-covariant formalism for inflation of scalar-curvature theories by adopting a differential geometric approach which treats the scalar fields as coordinates living on a field-space manifold. This ensures that our description of inflation is both conformally and reparameterization covariant. Our formulation gives rise to extensions of the usual Hubble and potential slow-roll parameters to generalized fully frame-covariant forms, which allow us to provide manifestly frame-invariant predictions for cosmological observables, such as the tensor-to-scalar ratio r, the spectral indices nR and nT, their runnings αR and αT, the non-Gaussianity parameter fNL, and the isocurvature fraction βiso. We examine the role of the field space curvature in the generation and transfer of isocurvature modes, and we investigate the effect of boundary conditions for the scalar fields at the end of inflation on the observable inflationary quantities. We explore the stability of the trajectories with respect to the boundary conditions by using a suitable sensitivity parameter. To illustrate our approach, we first analyze a simple minimal two-field scenario before studying a more realistic nonminimal model inspired by Higgs inflation. We find that isocurvature effects are greatly enhanced in the latter scenario and must be taken into account for certain values in the parameter space such that the model is properly normalized to the observed scalar power spectrum PR. Finally, we outline how our frame-covariant approach may be extended beyond the tree-level approximation through the Vilkovisky–De Witt formalism, which we generalize to take into account conformal transformations, thereby leading to a fully frame-invariant effective action at the one-loop level.http://www.sciencedirect.com/science/article/pii/S0550321317304005
collection DOAJ
language English
format Article
sources DOAJ
author Sotirios Karamitsos
Apostolos Pilaftsis
spellingShingle Sotirios Karamitsos
Apostolos Pilaftsis
Frame covariant nonminimal multifield inflation
Nuclear Physics B
author_facet Sotirios Karamitsos
Apostolos Pilaftsis
author_sort Sotirios Karamitsos
title Frame covariant nonminimal multifield inflation
title_short Frame covariant nonminimal multifield inflation
title_full Frame covariant nonminimal multifield inflation
title_fullStr Frame covariant nonminimal multifield inflation
title_full_unstemmed Frame covariant nonminimal multifield inflation
title_sort frame covariant nonminimal multifield inflation
publisher Elsevier
series Nuclear Physics B
issn 0550-3213
publishDate 2018-02-01
description We introduce a frame-covariant formalism for inflation of scalar-curvature theories by adopting a differential geometric approach which treats the scalar fields as coordinates living on a field-space manifold. This ensures that our description of inflation is both conformally and reparameterization covariant. Our formulation gives rise to extensions of the usual Hubble and potential slow-roll parameters to generalized fully frame-covariant forms, which allow us to provide manifestly frame-invariant predictions for cosmological observables, such as the tensor-to-scalar ratio r, the spectral indices nR and nT, their runnings αR and αT, the non-Gaussianity parameter fNL, and the isocurvature fraction βiso. We examine the role of the field space curvature in the generation and transfer of isocurvature modes, and we investigate the effect of boundary conditions for the scalar fields at the end of inflation on the observable inflationary quantities. We explore the stability of the trajectories with respect to the boundary conditions by using a suitable sensitivity parameter. To illustrate our approach, we first analyze a simple minimal two-field scenario before studying a more realistic nonminimal model inspired by Higgs inflation. We find that isocurvature effects are greatly enhanced in the latter scenario and must be taken into account for certain values in the parameter space such that the model is properly normalized to the observed scalar power spectrum PR. Finally, we outline how our frame-covariant approach may be extended beyond the tree-level approximation through the Vilkovisky–De Witt formalism, which we generalize to take into account conformal transformations, thereby leading to a fully frame-invariant effective action at the one-loop level.
url http://www.sciencedirect.com/science/article/pii/S0550321317304005
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AT apostolospilaftsis framecovariantnonminimalmultifieldinflation
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