Abstract
Recent observations constrain the amount of Dark Radiation ($\Delta N_{\rm eff}$) and may even hint towards a non-zero value of $\Delta N_{\rm eff}$. It is by now well-known that this puts stringent constraints on the sequestered Large Volume Scenario (LVS), i.e. on LVS realisations with the Standard Model at a singularity. We go beyond this setting by considering LVS models where SM fields are realised on 7-branes in the geometric regime. As we argue, this naturally goes together with high-scale supersymmetry. The abundance of Dark Radiation is determined by the competition between the decay of the lightest modulus to axions, to the SM Higgs and to gauge fields. The latter decay channel avoids the most stringent constraints of the sequestered setting. Nevertheless, a rather robust prediction for a substantial amount of Dark Radiation can be made. This applies both to cases where the SM 4-cycles are stabilised by D-terms and are small "by accident" as well as to fibred models with the small cycles stabilised by loops. Furthermore, we analyse a closely related setting where the SM lives at a singularity but couples to the volume modulus through flavour branes. We conclude that some of the most natural LVS settings with natural values of model parameters lead to Dark Radiation predictions just below the present observational limits. Barring a discovery, rather modest improvements of present Dark Radiation bounds can rule out many of these most simple and generic variants of the LVS.
Highlights
JHEP09(2014)140 compactifications — is most naturally caused by the decay of moduli
In this paper we examined predictions for the amount of Dark Radiation (DR) for string models employing the scheme of moduli stabilisation known as the Large Volume Scenario (LVS)
We focus on constructions beyond the sequestered LVS, which has already been examined in [5, 6]
Summary
We review DR predictions in the sequestered LVS from [5,6,7, 14]. In particular, we comment on how observational results for ∆Neff constrain this model and interplay with the SUSY breaking scale. In the sequestered LVS, the visible sector is realised by D3-branes at a singularity This scenario is attractive as gaugino and soft scalar masses are suppressed w.r.t. the gravitino mass. The decay rate of τb into SM fields depends on the realisation of the visible sector, which introduces a model-dependence into DR predictions. MP /V2 is parametrically lower than mτb ∼ MP /V3/2, in turn suppressing the decay rate into matter scalars w.r.t. Allowing additional Higgs doublets while fixing z = 1, the sequestered LVS is not ruled out by observation as long as nH > 4. This requires the field content of the visible sector to be extended beyond the MSSM. While sequestered models are in no way ruled out by current data, we believe it is desirable to examine alternative settings
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
