Ground state properties of a spin-52 frustrated triangular lattice antiferromagnet NH4Fe(PO3F)2

Abstract

Structural and magnetic properties of a two-dimensional spin-52 frustrated triangular lattice antiferromagnet NH4Fe(PO3F)2 are explored via x-ray diffraction, magnetic susceptibility, high-field magnetization, heat capacity, and 31P nuclear magnetic resonance experiments on a polycrystalline sample. The compound portrays distorted triangular units of the Fe3+ ions with anisotropic bond lengths. The magnetic susceptibility shows a broad maxima around Tmax 12 K, mimicking the short-range antiferromagnetic order of a low-dimensional spin system. The magnetic susceptibility and NMR shift could be modeled assuming the spin-5/2 isotropic triangular lattice model and the average value of the exchange coupling is estimated to be J/k B 1.7 K. This value of the exchange coupling is reproduced well from the saturation field of the pulse field data. It shows the onset of a magnetic ordering at T N 5.7 K, setting the frustration ratio of f = |θ CW|T N 5.7. Such a value of f reflects moderate magnetic frustration in the compound. The dM/dH vs H plots of the low temperature magnetic isotherms exhibit a sharp peak at H SF 1.45 T, suggesting a field-induced spin-flop transition and magnetic anisotropy. The rectangular shape of the 31P NMR spectra below T N unfolds that the ordering is commensurate antiferromagnet type. Three distinct phase regimes are clearly discerned in the H - T phase diagram, redolent of a frustrated magnet with in-plane (XY-type) anisotropy.

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