Dimensionless supersymmetry breaking couplings, flat directions, and the origin of intermediate mass scales

Abstract

The effects of supersymmetry breaking are usually parametrized by soft couplings of positive mass dimensions. However, realistic models also predict the existence of suppressed, but nonvanishing, dimensionless supersymmetry-breaking couplings. These couplings are technically hard, but do not lead to disastrous quadratic divergences in scalar masses, and may be crucial for understanding low-energy physics. In particular, analytic scalar quartic couplings that break supersymmetry can lead to intermediate scale vacuum expectation values along nearly flat directions. I study the one-loop effective potential for flat directions in the presence of dimensionless supersymmetry-breaking terms, and discuss the corresponding renormalization group equations. I discuss two applications: a minimal model of automatic R-parity conservation, and an extension of this minimal model which provides a solution to the μ problem and an invisible axion.