Towards Geometric D6-Brane Model Building on non-Factorisable Toroidal Z4-Orbifolds

Abstract

We present a geometric approach to D-brane model building on the non-factorisable torus backgrounds of T6/Z4, which are A3 × A3 and A3 × A1 × B2. Based on the counting of `short' supersymmetric three-cycles per complex structure vev, the number of physically inequivalent lattice orientations with respect to the anti-holomorphic involution R of the Type IIA/R orientifold can be reduced to three for the A3 × A3 lattice and four for the A3 × A1 × B2 lattice. While four independent three-cycles on A3 × A3 cannot accommodate phenomenologically interesting global models with a chiral spectrum, the eight-dimensional space of three-cycles on A3 × A1 × B2 is rich enough to provide for particle physics models, with several globally consistent two- and four-generation Pati-Salam models presented here. We further show that for fractional sLag three-cycles, the compact geometry can be rewritten in a (T2)3 factorised form, paving the way for a generalisation of known CFT methods to determine the vector-like spectrum and to derive the low-energy effective action for open string states.