2012
DOI: 10.1103/physrevd.85.023525
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Gauge field production in axion inflation: Consequences for monodromy, non-Gaussianity in the CMB, and gravitational waves at interferometers

Abstract: Models of inflation based on axions, which owe their popularity to the robustness against UV corrections, have also a very distinct class of signatures. The relevant interactions of the axion are a non-perturbative oscillating contribution to the potential and a shift-symmetric coupling to gauge fields. We review how these couplings affect the cosmological perturbations via a unified study based on the in-in formalism. We then note that, when the inflaton coupling to gauge fields is high enough to lead to inte… Show more

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Cited by 314 publications
(465 citation statements)
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References 119 publications
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“…63 Besides the model-independent gravitational wave signal, a host of additional modeldependent signatures have been explored, including oscillations in the power spectrum [36], deviations from scale-invariance [759], non-Gaussianity [37,760], chiral gravitational waves [260,759], and primordial black holes [761]. Since all of these effects are tied to the underlying axion shift symmetry, one has the hope of finding correlated signatures across different observational channels.…”
Section: Phenomenologymentioning
confidence: 99%
See 1 more Smart Citation
“…63 Besides the model-independent gravitational wave signal, a host of additional modeldependent signatures have been explored, including oscillations in the power spectrum [36], deviations from scale-invariance [759], non-Gaussianity [37,760], chiral gravitational waves [260,759], and primordial black holes [761]. Since all of these effects are tied to the underlying axion shift symmetry, one has the hope of finding correlated signatures across different observational channels.…”
Section: Phenomenologymentioning
confidence: 99%
“…65 We will assume α ≤ 1. The case α 1 is discussed in [767], while estimates for α in type IIB string theory appear in [759]. Both bottom-up and top-down naturalness of the regime α 1 remain to be established.…”
Section: Phenomenologymentioning
confidence: 99%
“…2.4) naturally allows (from an effective field theory point of view) for a coupling between a pseudoscalar axion inflaton field and a gauge field of the type L ⊃ −(α/4 f )φF µνF µν , where the parameter α is dimensionless and f is the axion decay constant (F µν = µνγβ F γβ /2). This scenario has a rich and interesting phenomenology both for scalar and tensor primordial fluctuations (see, e.g., Sorbo 2011;Barnaby et al , 2012cLinde et al 2013;Meerburg & Pajer 2013;Ferreira & Sloth 2014). Gauge field quanta are produced by the background motion of the inflaton field, and these in turn source curvature perturbations through an inverse decay process of the gauge field.…”
Section: Non-gaussianity From Gauge-field Production During Axion Infmentioning
confidence: 99%
“…In non-supersymmetric theories the coupling aFF of vectors with axion field a(x) was studied intensely in QFT and in applications to cosmology, see for example [47] and references therein. The couplings of vectors to moduli fields e φ F F were also studied in various situations in QFT and cosmology.…”
Section: Jhep12(2011)096mentioning
confidence: 99%