Exchange parameters of copper-based quasi-two-dimensional Heisenberg magnets measured using high magnetic fields and muon-spin rotation

Abstract

Pulsed-field magnetization experiments (fields B of up to 85 T and temperatures T down to 0.4 K) are reported on nine organic Cu-based two-dimensional (2D) Heisenberg magnets. All compounds show a low-T magnetization that is concave as a function of B, with a sharp ``elbow'' transition to a constant value at a field B c. Monte-Carlo simulations including a finite interlayer exchange energy J quantitatively reproduce the data; the concavity indicates the effective dimensionality and B c is an accurate measure of the in-plane exchange energy J. Using these values and Ne\'el temperatures measured by muon-spin rotation, it is also possible to obtain a quantitative estimate of |J/J|. In the light of these results, it is suggested that in magnets of the form [Cu(HF2)(pyz)2]X, where X is an anion, the sizes of J and J are controlled by the tilting of the pyrazine (pyz) molecule with respect to the 2D planes.