Antiferromagnetism of Zn2VO(PO4)2 and the dilution with Ti4+

Abstract

We report static and dynamic properties of the antiferromagnetic compound Zn2(VO)(PO4)2, and the consequences of non-magnetic Ti4+ doping at the V4+ site. 31P nuclear magnetic resonance (NMR) spectra and spin-lattice relaxation rate (1/T1) consistently show the formation of the long-range antiferromagnetic order below TN= 3.8-3.9\,K. The critical exponent β=0.33 0.02 estimated from the temperature dependence of the sublattice magnetization measured by 31P NMR at 9.4\,MHz is consistent with universality classes of three-dimensional spin models. The isotropic and axial hyperfine couplings between the 31P nuclei and V4+ spins are A hf iso = (9221 100) Oe/μ B and A hf ax = (1010 50) Oe/μ B, respectively. Magnetic susceptibility data above 6.5\,K and heat capacity data above 4.5\,K are well described by quantum Monte-Carlo simulations for the Heisenberg model on the square lattice with J 7.7\,K. This value of J is consistent with the values obtained from the NMR shift, 1/T1 and electron spin resonance (ESR) intensity analysis. Doping Zn2VO(PO4)2 with non-magnetic Ti4+ leads to a marginal increase in the J value and the overall dilution of the spin lattice. In contrast to the recent ab initio results, we find neither evidence for the monoclinic structural distortion nor signatures of the magnetic one-dimensionality for doped samples with up to 15\% of Ti4+. The N\'eel temperature T N decreases linearly with increasing the amount of the non-magnetic dopant.