English

The large $N$ factorization does not hold for arbitrary multi-trace observables in random tensors

Mathematical Physics 2025-06-19 v1 High Energy Physics - Theory Combinatorics math.MP Probability

Abstract

We consider real tensors of order DD, that is DD-dimensional arrays of real numbers Ta1a2aDT_{a^1a^2 \dots a^D}, where each index aca^c can take NN values. The tensor entries Ta1a2aDT_{a^1a^2 \dots a^D} have no symmetry properties under permutations of the indices. The invariant polynomials built out of the tensor entries are called trace invariants. We prove that for a Gaussian random tensor with D3D\ge 3 indices (that is such that the entries Ta1a2aDT_{a^1a^2 \dots a^D} are independent identically distributed Gaussian random variables) the cumulant, or connected expectation, of a product of trace invariants is not always suppressed in scaling in NN with respect to the product of the expectations of the individual invariants. Said otherwise, not all the multi-trace expectations factor at large NN in terms of the single-trace ones and the Gaussian scaling is not subadditive on the connected components. This is in stark contrast to the D=2D=2 case of random matrices in which the multi-trace expectations always factor at large NN. The best one can do for D3D\ge 3 is to identify restricted families of invariants for which the large NN factorization holds and we check that this indeed happens when restricting to the family of melonic observables, the dominant family in the large NN limit.

Cite

@article{arxiv.2506.15362,
  title  = {The large $N$ factorization does not hold for arbitrary multi-trace observables in random tensors},
  author = {Razvan Gurau and Felix Joos and Benjamin Sudakov},
  journal= {arXiv preprint arXiv:2506.15362},
  year   = {2025}
}
R2 v1 2026-07-01T03:23:27.918Z