Dark Radiation predictions from general Large Volume Scenarios

Muia

Shukla

2016

J. High Energ. Phys.

We present concrete embeddings of fibre inflation models in globally consistent type IIB Calabi-Yau orientifolds with closed string moduli stabilisation. After performing a systematic search through the existing list of toric Calabi-Yau manifolds, we find several examples that reproduce the minimal setup to embed fibre inflation models. This involves Calabi-Yau manifolds with h 1,1 = 3 which are K3 fibrations over a P 1 base with an additional shrinkable rigid divisor. We then provide different consistent choices of the underlying brane set-up which generate a non-perturbative superpotential suitable for moduli stabilisation and string loop corrections with the correct form to drive inflation. For each Calabi-Yau orientifold setting, we also compute the effect of higher derivative contributions and study their influence on the inflationary dynamics.

Section: Introductionmentioning

confidence: 99%

Global embedding of fibre inflation models

Muia

Shukla

2016

J. High Energ. Phys.

“…2 In this way, the decay rate of the lightest modulus to visible sector gauge bosons becomes comparable to the decay to bulk axions, and so the prediction for ∆N eff can become smaller. In fact, the simplest model with a shift-symmetric Higgs sector yields ∆N eff ≃ 0.5 [28]. However this case necessarily requires high-scale SUSY since without sequestering M soft ∼ m 3/2 (up to loop factors), and so from (1.2) we see that the cosmological bound m mod ∼ m 3/2 √ ǫ 30 TeV implies…”

Section: Jhep12(2015)152mentioning

confidence: 99%

“…[27] showed how sequestered LVS models where the Calabi-Yau (CY) volume is controlled by more than one divisor are ruled out since they predict huge values of extra dark radiation of order ∆N eff ∼ 10 4 . On the other hand, [28] focused on non-sequestered LVS models where the visible sector is realised via D7-branes wrapping the large cycle controlling the CY volume. 2 In this way, the decay rate of the lightest modulus to visible sector gauge bosons becomes comparable to the decay to bulk axions, and so the prediction for ∆N eff can become smaller.…”

Section: Jhep12(2015)152mentioning

confidence: 99%

See 1 more Smart Citation

General analysis of dark radiation in sequestered string models

Muia

2015

J. High Energ. Phys.

Abstract:We perform a general analysis of axionic dark radiation produced from the decay of the lightest modulus in the sequestered LARGE Volume Scenario. We discuss several cases depending on the form of the Kähler metric for visible sector matter fields and the mechanism responsible for achieving a de Sitter vacuum. The leading decay channels which determine dark radiation predictions are to hidden sector axions, visible sector Higgses and SUSY scalars depending on their mass. We show that in most of the parameter space of split SUSY-like models squarks and sleptons are heavier than the lightest modulus. Hence dark radiation predictions previously obtained for MSSM-like cases hold more generally also for split SUSY-like cases since the decay channel to SUSY scalars is kinematically forbidden. However the inclusion of string loop corrections to the Kähler potential gives rise to a parameter space region where the decay channel to SUSY scalars opens up, leading to a significant reduction of dark radiation production. In this case, the simplest model with a shift-symmetric Higgs sector can suppress the excess of dark radiation ∆N eff to values as small as 0.14, in perfect agreement with current experimental bounds. Depending on the exact mass of the SUSY scalars all values in the range 0.14 ∆N eff 1.6 are allowed. Interestingly dark radiation overproduction can be avoided also in the absence of a Giudice-Masiero coupling.

“…If the visible sector lives on D3-branes at singularities, the gauge kinetic function is set at tree-level by the dilaton, and so both the volume mode χ and the inflaton φ couple to visible sector gauge bosons only at loop level. All the other inflaton couplings to visible sector fields are further suppressed since [17][18][19][20][21]: (i) the couplings to quarks and leptons are chirality suppressed; (ii) depending on the level of sequestering of the visible sector from the sources of supersymmetry breaking, the decay of the inflaton to supersymmetric particles is either kinematically forbidden or mass suppressed; (iii) there is no tree-level inflaton coupling to Higgses induced by a Giudice-Masiero term in the Kähler potential since, as can be seen from (2.26), the volume mode V is given at leading order just by the heavy field χ. 3 Hence in the case of D3-branes, the main inflaton decay channel is into gauge bosons but the branching ratio into visible sector particles is negligible with respect to the one into hidden sector degrees of freedom since [69]:…”

Section: Visible Sector On D3-branesmentioning

confidence: 99%

Reheating and dark radiation after fibre inflation

J. Cosmol. Astropart. Phys.

Piovano

2019

We study perturbative reheating at the end of fibre inflation where the inflaton is a closed string modulus with a Starobinsky-like potential. We first derive the spectral index n s and the tensor-to-scalar ratio r as a function of the number of efoldings and the parameter R which controls slow-roll breaking corrections. We then compute the inflaton couplings and decay rates into ultra-light bulk axions and visible sector fields on D7-branes wrapping the inflaton divisor. This leads to a reheating temperature of order 10 10 GeV which requires 52 efoldings. Ultra-light axions contribute to dark radiation even if ∆N eff is almost negligible in the generic case where the visible sector D7-stack supports a non-zero gauge flux. If the parameter R is chosen to be small enough, n s 0.965 is then in perfect agreement with current observations while r turns out to be of order r 0.007. If instead the flux on the inflaton divisor is turned off, ∆N eff 0.6 which, when used as a prior for Planck data, requires n s 0.99. After R is fixed to obtain such a value of n s , primordial gravity waves are larger since r 0.01.