Physical Review X (Feb 2019)

Exotic Magnetic Field-Induced Spin-Superstructures in a Mixed Honeycomb-Triangular Lattice System

  • V. Ovidiu Garlea,
  • Liurukara D. Sanjeewa,
  • Michael A. McGuire,
  • Cristian D. Batista,
  • Anjana M. Samarakoon,
  • David Graf,
  • Barry Winn,
  • Feng Ye,
  • Christina Hoffmann,
  • Joseph W. Kolis

DOI
https://doi.org/10.1103/PhysRevX.9.011038
Journal volume & issue
Vol. 9, no. 1
p. 011038

Abstract

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The temperature–magnetic field phase diagram of the mixed honeycomb-triangular lattice system K_{2}Mn_{3}(VO_{4})_{2}CO_{3} is investigated by means of magnetization, heat-capacity, and neutron-scattering measurements. The results indicate that triangular and honeycomb magnetic layers undergo sequential magnetic orderings and act as nearly independent magnetic sublattices. The honeycomb sublattice orders at about 85 K in a Neél-type antiferromagnetic structure, while the triangular sublattice displays two consecutive ordered states at much lower temperatures, 3 and 2.2 K. The ground state of the triangular sublattice consists of a planar “Y” magnetic structure that emerges from an intermediate collinear “up-up-down” state. Applied magnetic fields parallel or perpendicular to the c axis induce exotic ordered phases characterized by various spin-stacking sequences of triangular layers that yield bilayer, three-layer, or four-layer magnetic superstructures. The observed superstructures cannot be explained in the framework of quasiclassical theory based only on nearest-neighbor interlayer coupling and point towards the presence of effective second-nearest-neighbor interactions mediated by fluctuations of the magnetic moments in the honeycomb sublattice.