2D XY Behavior observed in quasi-2D quantum Heisenberg antiferromagnets

The magnetic properties of a new family of molecular-based quasi-two dimension \(S=1/2\) Heisenberg antiferromagnets are reported. Three compounds, (\(Cu(pz)_2(ClO_4)_2\), \(Cu(pz)_2(BF_4)_2\), and \([Cu(pz)_2(NO_3)](PF_6)\)) contain similar planes of Cu\(^{2+}\) ions linked into magnetically square lattices by bridging pyrazine molecules (pz = \(C_4H_4N_2\)). The anions provide charge balance as well as isolation between the layers. Single crystal measurements of susceptibility and magnetization, as well as muon spin relaxation studies, reveal low ratios of N\'{e}el temperatures to exchange strengths (\(4.25 / 17.5 = 0.243\), \(3.80/15.3=0.248\), and \(3.05/10.8=0.282\), respectively) while the ratio of the anisotropy fields \(H_A\) (kOe) to the saturation field \(H_\mathrm{SAT}\) (kOe) are small (\(2.6/490 = 5.3\times10^{-3}\), \(2.4/430=5.5\times10^{-3}\), and \(0.07/300=2.3\times10^{-4}\), respectively), demonstrating close approximations to a 2D Heisenberg model. The susceptibilities of ClO\(_4\) and BF\(_4\) show evidence of an exchange anisotropy crossover (Heisenberg to \(XY\)) at low temperatures; their ordering transitions are primarily driven by the \(XY\) behavior with the ultimate 3D transition appearing parasitically. The PF\(_6\) compound remains Heisenberg-like at all temperatures, with its transition to the N\'{e}el state due to the interlayer interactions. Effects of field-induced anisotropy have been observed.