Sequestered String Models: Supersymmetry Breaking and Cosmological Applications

TL;DR

This thesis explores sequestered string models that achieve a hierarchy between supersymmetry breaking and particle masses, addressing cosmological constraints and their implications for dark matter, dark radiation, and early universe evolution.

Contribution

It introduces a detailed analysis of sequestered compactifications, demonstrating how they can reconcile low-energy SUSY with cosmological moduli constraints and explore their cosmological applications.

Findings

Hierarchy between SUSY-breaking scale and particle spectrum achieved

Moduli decay impacts cosmological evolution and observable predictions

Models produce non-thermal dark matter and dark radiation

Abstract

In the present thesis I studied the phenomenology arising from a class of string models called sequestered compactifications, which were born with the aim of getting low-energy SUSY from strings. This is not an easy task if combined with cosmological constraints, since the mechanism of moduli stabilization fixes both the scale of supersymmetric particles and the scale of moduli, which tend to be of the same order. However, if on the one hand supersymmetric particles with TeV mass are desired in order to address the hierarchy problem, on the other hand the cosmological moduli problem requires the moduli to be heavier than 100 TeV. The specific setup of sequestered compactifications makes this hierarchy achievable, at least in principle: as in these models the visible sector is located on a stack of D3-branes at singularities, a physical separation between the visible degrees of freedom and the SUSY-breaking sources takes place. Such decoupling translates into a hierarchy between the scale of SUSY-breaking and the spectrum of supersymmetric particles. Moreover, it is interesting to notice that moduli are the four-dimensional manifestation of the existence of extra-dimensions, and then their presence is a common feature of all string compactifications. Since they are gravitationally coupled, they could decay late in the history of the universe, affecting in a significant way its cosmological evolution. Possible deviations of the cosmological observables from the values predicted by the standard Hot Big Bang Theory constitute an interesting alternative for the discovery of BSM physics, which is complementary to the particle physics search. For this reason in addition to SUSY-breaking in sequestered models, I also studied several cosmological scenarios arising from them, such as production of non-thermal dark matter and dark radiation, reheating from moduli decay and inflation.