Universal Quantum Suppression in Frustrated Ising Magnets across the Quasi-1D to 2D Crossover via Quantum Annealing

Abstract

Quantum magnets in the MNb2O6 and BaCo2V2O8 families realise frustrated transverse-field Ising models whose competing ferromagnetic and antiferromagnetic couplings generate a sign problem provably intractable for quantum Monte Carlo at any system size, leaving their quantum phase boundaries numerically Inaccessible. Using a D-Wave Advantage2 quantum annealer at L≤27 (729 spins), we obtain the large-L critical points for this model family, measuring quantum-driven transitions at gcQPU∈\0.286,\,0.210,\,0.156,\,0.093\ for α∈\1.0,\,0.7,\,0.5,\,0.3\, where the analytically exact classical threshold is gcclass(α)=2α/3. The suppression ratio r(α) exhibits a sharp two-regime structure: the three quasi-1D geometries (α≤0.7) are mutually consistent with a universal plateau r=0.450 (2/dof=1.10, p=0.33), demonstrating that quantum fluctuations destroy approximately 55\% of the classical FM stability window independently of coupling anisotropy, while r steps down to the 2D limit above the empirical crossover scale α*≈0.7. Inner Binder cumulant pairs, which converge fastest to the thermodynamic limit, resolve r(1.0)≈0.412 and a step r=0.0380.015 from the quasi-1D plateau. A four-point linear fit r(α)=0.494-0.063\,α summarises both regimes; its α0 intercept recovers the exact 1D result of Pfeuty within 1.7 standard deviations, and its slope is a lower bound on the true crossover amplitude concentrated in α∈[α*,1]. Two sequential blind predictions, confirmed at 0.2σ and 0.7σ before each measurement, validate the crossover law. All four geometries show a direct ferromagnet-to-paramagnet transition, complete quantum ergodicity (f uniq=1.000), and null valence-bond solid order.

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