Breaking of four-fold rotational symmetry driven by stripe-type magnetism in semiconducting KFe_0.8Ag_1.2Te₂

Superconductivity in the iron pnictides and chalcogenides emerges in the vicinity of an electronic nematic state, whose driving force remains controversial. We use X-ray and neutron scattering to study the semiconducting alkaline metal iron chalcogenide KFe_0.8Ag_1.2Te₂, that is structurally analogous to the prototypical iron pnictide BaFe₂As₂. We find that KFe_0.8Ag_1.2Te₂ realizes isolated 2x2 Fe blocks, separated by nonmagnetic Ag atoms. Long-range magnetic order sets in below T_N = 35 K, with magnetic moments within each Fe block ordering into a stripe-type configuration. A structural transition that breaks four-fold rotational symmetry of the lattice accompanies the magnetic transition, resulting in different lattice spacings along the two orthogonal Fe-Fe bond directions. This difference in lattice spacings is similar to that in BaFe₂As₂ in magnitude, and like BaFe₂As₂, the lattice spacing is longer along the antiferromagnetically aligned Fe-Fe direction. Since KFe_0.8Ag_1.2Te₂ is a semiconductor, local-moment magnetism is likely responsible for driving the breaking of four-fold rotational symmetry, and similar magnetic interactions may play an important role in the superconducting alkaline metal iron chalcogenides.