Spindynamics in the antiferromagnetic phases of the Dirac metals AMnBi2 (A= Sr, Ca)

Abstract

The square Bi layers in AMnBi2 (A = Sr, Ca) host Dirac fermions which coexist with antiferromagnetic order on the Mn sublattice below TN = 290\,K (Sr) and 270\,K (Ca). We have measured the spin-wave dispersion in these materials by triple-axis neutron spectroscopy. The spectra show pronounced spin gaps of 10.2(2)\,meV (Sr) and 8.3(8)\,meV (Ca) and extend to a maximum energy transfer of 61 - 63\,meV. The observed spectra can be accurately reproduced by linear spin-wave theory from an Heisenberg effective spin Hamiltonian. Detailed global fits of the full magnon dispersion are used to determine the in-plane and inter-layer exchange parameters as well as on the magnetocrystalline anisotropy constant. To within experimental error we find no evidence that the magnetic dynamics are influenced by the Dirac fermions.