Parity superselection obstructs monogamy of mutual information in free fermions
Abstract
We prove that free fermions in the spin (tensor product) factorization violate monogamy of mutual information: I3spin > 0 for adjacent strips of width w 6 at all Fermi momenta, and for all w at z = kF w < z* ≈ 1.329. Many-body computation at w=6 via the G-matrix formula maps the scaling-limit function I3spin(z): it has a minimum of 0.100 at z ≈ 1.5, numerically establishing the conjecture I3spin > 0 for all z and w. The proof rests on an exact identity: the fermionic and spin reduced density matrices of disjoint regions A, D separated by B differ by the parity insertion (-1)NB in the partial trace. A Perron--Frobenius argument proves element-wise coherence damping; for free fermions, an independent Gaussian bound gives the entropy ordering SAD 0. Exact diagonalization confirms this for interacting fermions. DMRG on the t-V chain shows that the factorization contribution exceeds the genuine interaction contribution to I3 by a factor of 8, accounting for 80\% of the deviation in spin-basis numerics. Strong repulsion (K 0.7) restores monogamy. Conversely, Z2 parity superselection enforces I3 0 at all fillings (proved for w 3), with the ratio of parity entropy to quantum excess approaching 2 2/(3(4/3)) = 1.606. Any use of I3 as a diagnostic for holographic duality, quantum chaos, or Fermi surface topology must specify the operator algebra; without this, the sign of I3 is ambiguous.
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