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In frustrated quantum magnets the empirically found quantum-to-classical correspondence (QCC) matches the real-space static susceptibility pattern of a quantum spin-1/2 model with its classical counterpart computed at a certain elevated temperature. This puzzling relation was observed via bold line diagrammatic Monte Carlo simulations in dimensions two and three, where the matching was within error bars and seemed valid down to the lowest accessible temperatures T about an order of magnitude smaller than the exchange coupling J. Here we employ resummed spin diagrammatic perturbation theory to show analytically that the QCC breaks at fourth order in J/T and provide the approximate mapping between classical and quantum temperatures. Our treatment further reveals that QCC is an indication of the surprising accuracy with which static correlators can be approximated by a simple renormalized mean-field form. We illustrate this for all models discussed in the context of QCC so far, including a recent example of the S=1 material K₂Ni₂ (SO₄) ₃. The success of the mean-field form is traced back to partial diagrammatic cancellations.
Schneider et al. (Fri,) studied this question.