An Exact Conjugation Identity for the Many-Body Wilson-Loop Beyond Quantization

Abstract

Constraints on the unquantized many-body holonomy are less explored than their quantized counterparts. Here we realize an unquantized regime by tuning the bond dimerization δ and the staggered potential in a dimerized staggered Hubbard ring at half filling. For the tuned parameter sets, a finite excitation gap persists along the U(1) twist cycle θ∈[0,2π], so that the ground state |δ(θ) is separated from the excited states. The many-body Wilson loop is therefore well defined from the ground-state family \|δ(θ);\,θ∈[0,2π]\. In this setup, we show an exact many-body Wilson loop conjugation identity, W(-δ)=W(δ)*, accumulated along a cycle parametrized by θ. Importantly, the identity persists in regimes where the Berry phase γ- W varies continuously. We demonstrate the identity numerically using the density-matrix renormalization group (DMRG) method. The identity extends to other models where the flux-threaded ground-state family along the closed θ-cycle is mapped to the reversed cycle. More generally, the identity can be viewed as a Wilson-loop-level constraint that contains the Berry phase pinning as a fixed-point corollary. Beyond its conceptual content, the identity provides a symmetry-based consistency check for numerical evaluations of Berry phases in interacting systems. It also justifies the signal-to-noise ratio improvement in Monte Carlo simulations by performing simulations at both δ and -δ and averaging W(δ) with W(-δ)*.

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