English

Large-$N$ Random Matrix Gravity and the Double Hierarchy Problem

High Energy Physics - Theory 2021-06-02 v2 General Relativity and Quantum Cosmology

Abstract

Why are the cosmological constant, electroweak and Planck scales so different? This ``double hierarchy" problem, where ΛMEW2Mp2\Lambda \ll M^2_{EW} \ll M^2_p, is one of the most pressing in fundamental physics. We show that in a theory of NN randomly coupled massive gravitons at the electroweak scale, these scales are linked precisely by such a double hierarchy for large NN, with intriguing cosmological consequences. Surprisingly, in all the physical scales, only one massless graviton emerges which is also, effectively, the only one that is coupled to matter, giving rise to standard Einstein gravity, with Mp2Gμν=TμνM_p^2\, G_{\mu\nu}= T_{\mu\nu} at large NN. In addition there is a tower of massive gravitons, the lightest of which can drive late-time acceleration. In this scenario, the observed empirical relation ΛMp2MEW4\Lambda\, M_p^2 \sim M_{EW}^4 as well as the double hierarchy, arise naturally since ΛMEW2/N\Lambda \sim M^2_{EW}/\sqrt{N} and Mp2NMEW2M^2_p \sim \sqrt{N}M_{EW}^2.

Keywords

Cite

@article{arxiv.2004.01067,
  title  = {Large-$N$ Random Matrix Gravity and the Double Hierarchy Problem},
  author = {Nima Khosravi},
  journal= {arXiv preprint arXiv:2004.01067},
  year   = {2021}
}

Comments

the arguments became more clear. comments are welcome!

R2 v1 2026-06-23T14:36:56.452Z