Magnetic ordering and spin dynamics in S=5/2 staggered triangular lattice antiferromagnet Ba2MnTeO6

Abstract

We report studies of the magnetic properties of a staggered stacked triangular lattice Ba2MnTeO6 using magnetic susceptibility, specific heat, neutron powder diffraction and inelastic neutron scattering measurements, as well as first principles density functional theory calculations. Neutron diffraction measurements reveal an antiferromagnetic order with a propagated vector k=(0.5, 0.5, 0) and N\'eel transition temperature of TN≈20 K. The dominant interaction derived from the Curie-Weiss fitting to the inverse DC susceptibility is antiferromagnetic. Through modelling the INS spectrum with the linear spin wave theory, the magnetic exchange interactions for the nearest intralayer, nearest interlayer, and next nearest interlayer are determined to be J1=0.27(3),J2=0.27(3), and J3=-0.05(1) meV, respectively, and a small value of easy-axis anisotropy of Dzz=-0.01 meV is introduced. We derive a magnetic phase diagram that reveals that it is the competition between J1, J2, and J3 that stabilizes the collinear stripe-type antiferromagnetic order.