Twofold universality of large-N melonic random tensors

Abstract

We construct a measure that exhibits two aspects of a new type of universality and dramatically simplifies the integration of tensors Ta1,a2,…,aD ∈ C (a1,…,aD=1,…,N) at large N. In contrast to matrix integration, in which matrix traces canonically yield the integrand, tensors need additional information (equivalent to a D-coloured graph B) to contract their indices and form a tensor trace B(T). We show that, whenever each B1,…, Bn can be obtained by a recursive construction known as melonicity, then the leading order in N of the integral of B1(T) B2(T) ·s Bn(T) is independent of the -- often intricate -- combinatorics of the traces Bi, but also, to our surprise, independent of D as far as D≥ 3. Instead, at large N, these integrals are some functions (indexed by n) of the number of vertices 2pi of Bi which we call melonic polynomials. Melonic traces cumulants with respect to any ('interacting') measure \[ \-ND-1 Σi=1m gi Bi(T)\ dμ0(T) (g1,…,gm ∈ R, dμ0(T) =the tensor Gaussian) \] with each Bi melonic, can be computed with our universal measure that replaces each Bi by a canonical trace depending only on pi. We prove that any two melonic tensor models are indistinguishable at large-N, independently of the number of tensor indices (first universality aspect), and of the fine-grainedness of their interactions (second universality), being a sufficient condition that the couplings (the parameters gi above) agree and their respective traces are monomials with the same degree in T.

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