R\'enyi exponent landscape of multipartite entanglement in free-fermion systems

Abstract

We show that the R\'enyi tripartite information I3(α) of free fermions exhibits a qualitatively α-dependent scaling at small Fermi momentum, in sharp contrast to bipartite entropy where only the prefactor changes. In the rank-1 regime (z = kF w 1), I3(α) receives contributions from two competing channels -- a fractional-moment channel zα (active for non-integer α) and a polynomial channel zm from the first nonvanishing inclusion-exclusion moment σm -- yielding the scaling exponent βm(α) = (α, m) for m-partite information of m adjacent strips. Integer R\'enyi indices α = 2, 3, … are anomalous: the fractional channel closes and the exponent jumps to m or higher. A direct consequence is a replica obstruction: Im(n)/Im(1) zm-1 0 for all integer n ≥ 2, so the leading von Neumann signal cannot be reconstructed from integer R\'enyi data at the level of leading scaling -- a situation with no bipartite analog. Conversely, negativity-based measures (α = 1/2) give a 20× enhanced signal compared to von Neumann. We derive the underlying product formula for the coefficient c(wA, wB, wD), prove an m-partite generating function for the inclusion-exclusion moments, and verify all results numerically to high precision.

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