Inflation after WMAP3: confronting the slow-roll and exact power spectra with CMB data

Martin, Jérôme; Ringeval, Christophe

doi:10.1088/1475-7516/2006/08/009

Cited by 235 publications

(396 citation statements)

References 142 publications

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“…[11,12] (see also subsequent works [13][14][15][16]), the epoch of reheating, the era during which the vacuum energy of the inflaton is converted into * Electronic address: jmartin@iap.fr † Electronic address: christophe.ringeval@uclouvain.be ‡ Electronic address: vincent.vennin@port.ac.uk radiation, impacts the predicted values of the scalar spectral index and tensor-to-scalar ratio for all inflationary models. As a result, reducing uncertainties on the measured values of these two parameters provides some nontrivial information on how reheating proceeds, even if inflation is as simple as a slow-roll single-field scenario [17].…”

Section: Introductionmentioning

confidence: 99%

“…Within a given model of inflation, predicting the scalar spectral index and tensor-to-scalar ratio requires us to specify a value for the so-called rescaled reheating parameter R reh [11]. More specifically, once R reh is given, one can uniquely determine the number of e-folds before the end of inflation at which an observable mode k * crosses the Hubble radius [18], a quantity which is required to get the actual values of the observed slowroll parameters [19,20].…”

Section: Introductionmentioning

confidence: 99%

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Information gain on reheating: The one bit milestone

2016

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We show that the Planck 2015 and BICEP2/KECK measurements of the cosmic microwave background (CMB) anisotropies provide together an information gain of 0.82 ± 0.13 bits on the reheating history over all slow-roll single-field models of inflation. This corresponds to a 40% improvement compared to the Planck 2013 constraints on the reheating. Our method relies on an exhaustive CMB data analysis performed over nearly 200 models of inflation to derive the Kullback-Leibler entropy between the prior and the fully marginalized posterior of the reheating parameter. This number is a weighted average by the Bayesian evidence of each model to explain the data thereby ensuring its fairness and robustness.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Information gain on reheating: The one bit milestone

2016

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“…We found however that in a large part of the parameter space in which a bounce is realized (see Section III), the spectrum of CMB multipoles (Fig. 9) is merely modified in a way reminiscent of superimposed oscillations, a possibility that has attracted some attention in recent years [33], and was found to be not inconsistent with the data. Any oscillations in the matter power spectrum or CMB multipoles are expected to be mostly smoothed out either by transfer functions or observational windowing functions.…”

Section: Discussionmentioning

confidence: 73%

“…This can however be handled by assuming the bounce-making negative energy component to be merely phenomenological, acting only for a short time, the bounce duration, in general assumed comparable with the Planck scale. In any case, there are no generic properties that can be derived in a model-independent way as in slow-roll inflation [33]. Very often, though, it is found that a reasonable model connects two almost de Sitter phases.…”

Section: Introductionmentioning

confidence: 99%

Classical bounce: Constraints and consequences

2008

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We perform a detailed investigation of the simplest possible cosmological model in which a bounce can occur, namely that where the dynamics is led by a simple massive scalar field in a general selfinteracting potential and a background spacetime with positively curved spatial sections. By means of a phase space analysis, we give the conditions under which an initially contracting phase can be followed by a bounce and an inflationary phase lasting long enough (i.e., at least 60-70 e-folds) to suppress spatial curvature in today's observable universe. We find that, quite generically, this realization requires some amount of fine-tuning of the initial conditions. We study the effect of this background evolution on scalar perturbations by propagating an initial power-law power spectrum through the contracting phase, the bounce and the inflationary phase. We find that it is drastically modified, both spectrally (k−mode mixing) and in amplitude. It also acquires, at leading order, an oscillatory component, which, once evolved through the radiation and matter dominated eras, happens to be compatible with observational data.

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“…However, recently there has been an interesting development [15,19,20] to distinguish various inflationary models by indirectly looking at the possible physically motivated reheating mechanism through the evaluation of a particular observable scale and the entropy density till to- , and equal number of e-folding parameters N re1 = N re2 .The light blue shaded region corresponds to the 1σ bounds on ns from Planck. The brown shaded region corresponds to the 1σ bounds of a further CMB experiment with sensitivity ±10 −3 [17,18], using the same central ns value as Planck.…”

Section: Constraining Through Reheating Predictionsmentioning

confidence: 99%

Constraining scalar-Gauss-Bonnet inflation by reheating, unitarity, and Planck data

2017

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We revisit the inflationary dynamics in detail for theories with Gauss-Bonnet gravity coupled to scalar functions, in light of the Planck data. Considering the chaotic inflationary scenario, we constrain the parameters of two models involving inflaton-Gauss-Bonnet coupling by current Planck data. For non zero inflaton-Gauss-Bonnet coupling β, an inflationary analysis provides us a big cosmologically viable region in the space of (m, β), where m is the mass of inflaton. However, we study further on constraining β arising from reheating considerations and unitarity of tree-level amplitude involving we have studied the constraints on β arising from reheating considerations and unitarity of tree level amplitude involving 2 graviton → 2 graviton (hh → hh) scattering. Our analysis, particularly on reheating significantly reduces the parameter space of (m, β) for all models. he quadratic Gauss-Bonnet coupling parameter turns out to be more strongly constrained than that of the linear coupling. For the linear Gauss-Bonnet coupling function, we obtain β 10 3 , with the condition β(m/M P ) 2

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Inflation after WMAP3: confronting the slow-roll and exact power spectra with CMB data

Cited by 235 publications

References 142 publications

Information gain on reheating: The one bit milestone

Information gain on reheating: The one bit milestone

Classical bounce: Constraints and consequences

Constraining scalar-Gauss-Bonnet inflation by reheating, unitarity, and Planck data

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