English

Supersymmetric Vacua in Random Supergravity

High Energy Physics - Theory 2015-06-05 v1

Abstract

We determine the spectrum of scalar masses in a supersymmetric vacuum of a general N=1 supergravity theory, with the Kahler potential and superpotential taken to be random functions of N complex scalar fields. We derive a random matrix model for the Hessian matrix and compute the eigenvalue spectrum. Tachyons consistent with the Breitenlohner-Freedman bound are generically present, and although these tachyons cannot destabilize the supersymmetric vacuum, they do influence the likelihood of the existence of an `uplift' to a metastable vacuum with positive cosmological constant. We show that the probability that a supersymmetric AdS vacuum has no tachyons is formally equivalent to the probability of a large fluctuation of the smallest eigenvalue of a certain real Wishart matrix. For normally-distributed matrix entries and any N, this probability is given exactly by P = exp(-2N^2|W|^2/m_{susy}^2), with W denoting the superpotential and m_{susy} the supersymmetric mass scale; for more general distributions of the entries, our result is accurate when N >> 1. We conclude that for |W| \gtrsim m_{susy}/N, tachyonic instabilities are ubiquitous in configurations obtained by uplifting supersymmetric vacua.

Keywords

Cite

@article{arxiv.1207.2763,
  title  = {Supersymmetric Vacua in Random Supergravity},
  author = {Thomas C. Bachlechner and David Marsh and Liam McAllister and Timm Wrase},
  journal= {arXiv preprint arXiv:1207.2763},
  year   = {2015}
}

Comments

26 pages, 6 figures

R2 v1 2026-06-21T21:34:12.570Z