Quasi-two-dimensional magnetism and antiferromagnetic ground state in Li2FeSiO4

Abstract

Our experimental (neutron diffraction, M\"ossbauer spectroscopy, magnetic susceptibility, specific heat) and numerical studies on the evolution of short- and long-range magnetic order in γ II-Li\(2\)FeSiO\(4\) suggest a quasi-two-dimensional (2D) nature of magnetism. The experimental data obtained on single crystals imply long-range antiferromagnetic order below T N= 17~K. A broad maximum in magnetic susceptibility at T m 28~K, observation of magnetic entropy changes up to 100~K and anisotropy in are indicative of low-dimensional magnetism and suggest short-range magnetic correlations up to 200~K. Neutron diffraction shows that long-range antiferromagnetic order is characterised by the propagation vector k=(1/2,0,1/2). The ordered moment μ = 2.50(2) μB /Fe, at T = 1.5~K, is along the crystallographic a-axis. This is consistent with the observed static hyperfine field of B hyp=14.8(3)\,T by M\"ossbauer spectroscopy which indicates significant orbital contributions. The temperature dependence of B hyp yields the critical exponent β=0.116(12) which is in the regime of the 2D Ising behaviour. LSDA+U studies exploiting the experimental spin structure suggest dominating magnetic exchange coupling within the ac-layers (i.e., J3 -6~K and J6-2~K) while interlayer coupling is much smaller and partly frustrated. This confirms the 2D nature of magnetism and is in full agreement with the experimental findings.