Dimensional Reduction of Supersymmetric Gauge Theories

TL;DR

This dissertation explores the dimensional reduction of ten-dimensional supersymmetric gauge theories over coset spaces, leading to four-dimensional models that can extend the Standard Model, and investigates noncommutative geometry's role in particle physics and gravity.

Contribution

It identifies four-dimensional models from string-inspired gauge theories that extend the Standard Model and examines noncommutative geometry's impact on particle physics and gravity.

Findings

Extensions of the Standard Model based on Pati-Salam group are achievable.

Dimensional reduction models are renormalizable.

Noncommutative geometry influences Ricci curvature in gravity theories.

Abstract

Main objective of the present dissertation is the investigation for all the possible low energy models which emerge in four dimensions by the dimensional reduction of a gauge theory over multiple connected coset spaces. The higher dimensional gauge theory is chosen to be the one that the Heterotic string theory suggests: (i) it is defined in ten dimensions, (ii) it is based on the E(8) x E(8) symmetry group and (iii) it is N=1 globally supersymmetric. The search of all four-dimensional gauge theories resulting from the aforementioned dimensional reduction, is restricted only to models which are potentially interesting from a phenomenological point of view. This requirement constrain these models to come from one of the known Grand Unified Theories (GUTs) in an intermediate stage of the spontaneous symmetry breaking. Main result of my study is that extensions of the Standard Model (SM) which are based on the Pati-Salam group structure can be obtained in four dimensions. I furthermore review some interesting noncommutative generalizations of the above ideas and verify an important conclusion of a previous research work, namely that the particle physics models resulting from this particular dimensional reduction are renormalizable. Finally, assuming noncommutative characteristics for the four-dimensional Minkowski space, M^{4}, I examine a particular approach of noncommutative gravity. It turns out that the Ricci curvature tensor receives non-trivial contributions due to the noncommutative structure of the algebra describing the space, This conclusion suggests a possible fundamental connection between the noncommutative geometry and the theory of gravity.