Mass formulae and natural hierarchy in string effective supergravities

TL;DR

This paper investigates conditions under which a natural hierarchy between the gravitino mass and the Planck scale can occur in string-derived supergravity theories, emphasizing the role of symmetries and cancellations in the effective potential.

Contribution

It identifies specific conditions and symmetries that allow for a natural hierarchy in string effective supergravities, including explicit formulae for soft breaking terms.

Findings

Hierarchy can be achieved without fine-tuning in string supergravities.

Approximate scaling symmetries help maintain the hierarchy.

Explicit soft breaking terms are derived for these models.

Abstract

We study some conditions for the hierarchy $m_{3/2} << M_P$ to occur naturally in a generic effective supergravity theory. Absence of fine-tuning and perturbative calculability require that the effective potential has a sliding gravitino mass and vanishing cosmological constant, up to ${\cal O}(m_{3/2}^4)$ corrections. In particular, cancellation of quadratically divergent contributions to the one-loop effective potential should take place, including the `hidden sector' of the theory. We show that these conditions can be met in the effective supergravities derived from four-dimensional superstrings, with supersymmetry broken either at the string tree level via compactification, or by non-perturbative effects such as gaugino condensation. A crucial role is played by some approximate scaling symmetries, which are remnants of discrete target-space dualities in the large moduli limit. We derive explicit formulae for the soft breaking terms arising from this class of `large hierarchy compatible' (LHC) supergravities.