Some phenomenological aspects of Type IIB/F-theory string compactifications

TL;DR

This thesis explores Type IIB and F-theory compactifications, analyzing their phenomenological potential, SUSY breaking mechanisms, and flux effects, with implications for realistic Standard Model-like models and fermion hierarchies.

Contribution

It provides a comprehensive analysis of Type IIB and F-theory compactifications, including SUSY breaking and flux effects, with new calculations of Yukawas and matter wave functions.

Findings

SUSY breaking dominated by moduli in these models

Flux and instanton effects influence matter field properties

Results contribute to understanding fermion hierarchies

Abstract

This article is the PhD thesis of the author. It is focused on Type II compactifications because of the potential for the construction of realistic MSSM-like compactifications. In particular we concentrate in Type IIB Calabi-Yau orientifolds and its non-perturbative realization: F-theory. These sort of models, have attracted a lot of attention during recent years due to their phenomenological interest. The first part is devoted to an introductory survey of some concepts and aspects of Type II vacua like e.g. the low energy effective action or soft terms. It is also included a brief presentation of F-theory stressing the phenomenological interest of local models. In the second part we present an analysis of the theoretical and phenomenological issues of modulus dominated SUSY breaking. In addition it is examined its status in comparison with recent LHC data. Finally, the third part is devoted to the analysis of flux and instanton effects on local F-theory models. Yukawas and matter fields wave functions corresponding to these models are calculated. The results may allow for an understanding of the problem of fermion hierarchies in the Standard Model.