Particle theory

Improved Higgs naturalness with or without supersymmetry

Physical Review D 74 (2006) 075002 5pp

Authors:

SM West, B Gripaios

Kahler Potentials of Chiral Matter Fields for Calabi-Yau String Compactifications

ArXiv hep-th/0609180 (2006)

Authors:

Joseph P Conlon, Daniel Cremades, Fernando Quevedo

Abstract:

The Kahler potential is the least understood part of effective N=1 supersymmetric theories derived from string compactifications. Even at tree-level, the Kahler potential for the physical matter fields, as a function of the moduli fields, is unknown for generic Calabi-Yau compactifications and has only been computed for simple toroidal orientifolds. In this paper we describe how the modular dependence of matter metrics may be extracted in a perturbative expansion in the Kahler moduli. Scaling arguments, locality and knowledge of the structure of the physical Yukawa couplings are sufficient to find the relevant Kahler potential. Using these techniques we compute the `modular weights' for bifundamental matter on wrapped D7 branes for large-volume IIB Calabi-Yau flux compactifications. We also apply our techniques to the case of toroidal compactifications, obtaining results consistent with those present in the literature. Our techniques do not provide the complex structure moduli dependence of the Kahler potential, but are sufficient to extract relevant information about the canonically normalised matter fields and the soft supersymmetry breaking terms in gravity mediated scenarios.

Kahler Potentials of Chiral Matter Fields for Calabi-Yau String Compactifications

(2006)

Authors:

Joseph P Conlon, Daniel Cremades, Fernando Quevedo

Algorithmic Algebraic Geometry and Flux Vacua

Journal of High Energy Physics (2006)

Authors:

JA Gray, Andre Lukas, Yang-Hui He

Algorithmic algebraic geometry and flux vacua

Journal of High Energy Physics 2006:9 (2006)

Authors:

J Gray, YH He, A Lukas

Abstract:

We develop a new and efficient method to systematically analyse four dimensional effective supergravities which descend from flux compactifications. The issue of finding vacua of such systems, both supersymmetric and non-supersymmetric, is mapped into a problem in computational algebraic geometry. Using recent developments in computer algebra, the problem can then be rapidly dealt with in a completely algorithmic fashion. Two main results are (1) a procedure for calculating constraints which the flux parameters must satisfy in these models if any given type of vacuum is to exist; (2) a stepwise process for finding all of the isolated vacua of such systems and their physical properties. We illustrate our discussion with several concrete examples, some of which have eluded conventional methods so far. © SISSA 2006.