D-Branes at Singularities : A Bottom-Up Approach to the String Embedding of the Standard Model

TL;DR

This paper presents a bottom-up string theory approach using D-branes at singularities to construct semi-realistic particle physics models, including the Standard Model, with detailed examples and implications for supersymmetry and gauge coupling predictions.

Contribution

It introduces a novel bottom-up method for building particle physics models from string theory using D-branes at singularities, with explicit constructions and phenomenological insights.

Findings

Unique Z_3 orbifold predicts sin^2θ_W=3/14

Constructed explicit semi-realistic string models with three generations

Demonstrated embedding into Calabi-Yau and F-theory frameworks

Abstract

We propose a bottom-up approach to the building of particle physics models from string theory. Our building blocks are Type II D-branes which we combine appropriately to reproduce desirable features of a particle theory model: 1) Chirality ; 2) Standard Model group ; 3) N=1 or N=0 supersymmetry ; 4) Three quark-lepton generations. We start such a program by studying configurations of D=10, Type IIB D3-branes located at singularities. We study in detail the case of Z_N, N=1,0 orbifold singularities leading to the SM group or some left-right symmetricextension. In general, tadpole cancellation conditions require the presence of additional branes, e.g. D7-branes. For the N=1 supersymmetric case the unique twist leading to three quark-lepton generations is Z_3, predicting $\sin^2\theta_W=3/14=0.21$. The models obtained are the simplest semirealistic string models ever built. In the non-supersymmetric case there is a three-generation model for each Z_N, N>4, but the Weinberg angle is in general too small. One can obtain a large class of D=4 compact models by considering the above structure embedded into a Calabi Yau compactification. We explicitly construct examples of such compact models using Z_3 toroidal orbifolds and orientifolds, and discuss their properties. In these examples, global cancellation of RR charge may be achieved by adding anti-branes stuck at the fixed points, leading to models with hidden sector gravity-induced supersymmetry breaking. More general frameworks, like F-theory compactifications, allow completely $\NN=1$ supersymmetric embeddings of our local structures, as we show in an explicit example.