Implications of decoupling effects for one-loop corrected effective actions from superstring theory

TL;DR

This paper investigates how decoupling effects in one-loop corrected superstring-derived supersymmetric theories influence low-energy effective actions, revealing significant modifications to coupling predictions due to heavy-light field interactions.

Contribution

It provides a detailed calculation of decoupling effects in superstring-inspired supersymmetric theories, highlighting their impact on low-energy couplings and effective field theory predictions.

Findings

Decoupling effects introduce non-renormalizable couplings and log(M) terms.

These effects can alter low-energy coupling predictions by 10-50%.

Heavy-light field interactions significantly influence effective actions from superstring models.

Abstract

We study the decoupling effects in one-loop corrected N=1 supersymmetric theory with gauge neutral chiral superfields, by calculating the one-loop corrected effective Lagrangian that involves light and heavy fields with the mass scale M, and subsequently eliminating heavy fields by their equations of motion. In addition to new non-renormalizable couplings, we determine the terms that grow as log(M) and renormalize the fields and couplings in the effective field theory, in accordance with the decoupling theorem. However, in a theory derived from superstring theory, these terms can significantly modify low energy predictions for the effective couplings of light fields. For example, in a class of heterotic superstring vacua with an anomalous U(1) the vacuum restabilization introduces such decoupling effects which in turn correct the low energy predictions for certain couplings by 10-50%.